From 2b5036be3843e3b540f8023bd1d08e36423888e2 Mon Sep 17 00:00:00 2001 From: "Documenter.jl" Date: Tue, 22 Oct 2024 02:59:22 +0000 Subject: [PATCH] build based on 221d38c --- dev/.documenter-siteinfo.json | 2 +- dev/act.html | 2 +- dev/act_details.html | 2 +- dev/actors.html | 174 +- dev/cases.html | 6 +- dev/dd.html | 2 +- dev/dd_details.html | 2 +- dev/deps.html | 2 +- dev/develop.html | 2 +- dev/examples.html | 2 +- dev/imas.html | 2 +- dev/index.html | 2 +- dev/ini.html | 2 +- dev/ini_details.html | 2 +- dev/inits.html | 2 +- dev/install.html | 2 +- dev/install_omega.html | 2 +- dev/install_saga.html | 2 +- dev/license.html | 2 +- dev/notice.html | 2 +- dev/pubs.html | 2 +- dev/search_index.js | 2 +- dev/tutorial-024cc0d3.svg | 1921 ++++++++++++++++ dev/tutorial-0a086ad8.svg | 88 - ...ial-e04a72ee.svg => tutorial-23a1618d.svg} | 60 +- dev/tutorial-2d1a6275.svg | 279 --- ...ial-2b4ddd3f.svg => tutorial-3204abb6.svg} | 548 ++--- dev/tutorial-3a161e95.svg | 98 - ...ial-dcc2343b.svg => tutorial-3f276429.svg} | 422 ++-- dev/tutorial-4380f52d.svg | 175 -- dev/tutorial-4b6875e9.svg | 348 +++ dev/tutorial-4c16a91b.svg | 548 +++++ dev/tutorial-4c7c2c9c.svg | 62 + dev/tutorial-59fdcfbf.svg | 352 --- dev/tutorial-65eafd9b.svg | 175 ++ ...ial-ed442773.svg => tutorial-6659eb07.svg} | 460 ++-- dev/tutorial-6fd9bf00.svg | 668 ------ ...ial-4b965e09.svg => tutorial-70645110.svg} | 368 ++-- dev/tutorial-7ec10118.svg | 552 ----- dev/tutorial-7f1367d5.svg | 64 - dev/tutorial-8bb8de52.svg | 1922 ----------------- dev/tutorial-8fe119a2.svg | 279 +++ dev/tutorial-918d9508.svg | 657 ++++++ dev/tutorial-aa33ee93.svg | 279 +++ ...ial-fc924334.svg => tutorial-b42e05ec.svg} | 64 +- dev/tutorial-be0cb2ab.svg | 279 --- ...ial-9fa1ceb8.svg => tutorial-c14c7a35.svg} | 192 +- dev/tutorial-c97d5ed4.svg | 86 + ...ial-026f2600.svg => tutorial-d59647df.svg} | 228 +- dev/tutorial-f2697e03.svg | 99 + ...ial-dd6e0719.svg => tutorial-fd5f2605.svg} | 68 +- dev/tutorial.html | 256 ++- 52 files changed, 5915 insertions(+), 5902 deletions(-) create mode 100644 dev/tutorial-024cc0d3.svg delete mode 100644 dev/tutorial-0a086ad8.svg rename dev/{tutorial-e04a72ee.svg => tutorial-23a1618d.svg} (85%) delete mode 100644 dev/tutorial-2d1a6275.svg rename dev/{tutorial-2b4ddd3f.svg => tutorial-3204abb6.svg} (61%) delete mode 100644 dev/tutorial-3a161e95.svg rename dev/{tutorial-dcc2343b.svg => tutorial-3f276429.svg} (89%) delete mode 100644 dev/tutorial-4380f52d.svg create mode 100644 dev/tutorial-4b6875e9.svg create mode 100644 dev/tutorial-4c16a91b.svg create mode 100644 dev/tutorial-4c7c2c9c.svg delete mode 100644 dev/tutorial-59fdcfbf.svg create mode 100644 dev/tutorial-65eafd9b.svg rename dev/{tutorial-ed442773.svg => tutorial-6659eb07.svg} (90%) delete mode 100644 dev/tutorial-6fd9bf00.svg rename dev/{tutorial-4b965e09.svg => tutorial-70645110.svg} (94%) delete mode 100644 dev/tutorial-7ec10118.svg delete mode 100644 dev/tutorial-7f1367d5.svg delete mode 100644 dev/tutorial-8bb8de52.svg create mode 100644 dev/tutorial-8fe119a2.svg create mode 100644 dev/tutorial-918d9508.svg create mode 100644 dev/tutorial-aa33ee93.svg rename dev/{tutorial-fc924334.svg => tutorial-b42e05ec.svg} (84%) delete mode 100644 dev/tutorial-be0cb2ab.svg rename dev/{tutorial-9fa1ceb8.svg => tutorial-c14c7a35.svg} (86%) create mode 100644 dev/tutorial-c97d5ed4.svg rename dev/{tutorial-026f2600.svg => tutorial-d59647df.svg} (83%) create mode 100644 dev/tutorial-f2697e03.svg rename dev/{tutorial-dd6e0719.svg => tutorial-fd5f2605.svg} (86%) diff --git a/dev/.documenter-siteinfo.json b/dev/.documenter-siteinfo.json index b1199671f..471f18409 100644 --- a/dev/.documenter-siteinfo.json +++ b/dev/.documenter-siteinfo.json @@ -1 +1 @@ -{"documenter":{"julia_version":"1.11.1","generation_timestamp":"2024-10-21T02:56:14","documenter_version":"1.7.0"}} \ No newline at end of file +{"documenter":{"julia_version":"1.11.1","generation_timestamp":"2024-10-22T02:58:45","documenter_version":"1.7.0"}} \ No newline at end of file diff --git a/dev/act.html b/dev/act.html index 778b5f035..e3b1cd022 100644 --- a/dev/act.html +++ b/dev/act.html @@ -273,4 +273,4 @@ └─ ActorWholeFacility ├─ update_plasma └─ update_build - + diff --git a/dev/act_details.html b/dev/act_details.html index 7d4b628eb..e67301092 100644 --- a/dev/act_details.html +++ b/dev/act_details.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
GitHub
act.ActorBalanceOfPlant.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorBlanket.minimum_first_wall_thickness

Minimum first wall thickness

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.02
act.ActorBlanket.blanket_multiplier

Neutron thermal power multiplier in blanket

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.2
act.ActorBlanket.thermal_power_extraction_efficiency

Fraction of thermal power that is carried out by the coolant at the blanket interface, rather than being lost in the surrounding strutures.

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorBlanket.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCHEASE.free_boundary

Convert fixed boundary equilibrium to free boundary one

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.clear_workdir

Clean the temporary workdir for CHEASE

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.rescale_eq_to_ip

Scale equilibrium to match Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorCXbuild.rebuild_wall

Rebuild wall based on equilibrium

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCXbuild.n_points

Number of points used for cross-sectional outlines

  • Type: Entry{Int64}
  • Units: -
  • Default: 101
act.ActorCXbuild.divertor_size

Divertor size as fraction of plasma minor radius

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.4
act.ActorCXbuild.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCoreRadHeatFlux.N

Number of launched photons

  • Type: Entry{Int64}
  • Units: -
  • Default: 100000
act.ActorCoreRadHeatFlux.r

Vector of r at outermidplane

  • Type: Entry{Vector{Float64}}
  • Units: m
  • Default: Float64[]
act.ActorCoreRadHeatFlux.q

Vector of parallel power density at outer midplane

  • Type: Entry{Vector{Float64}}
  • Units: W m^-2
  • Default: Float64[]
act.ActorCoreRadHeatFlux.levels

If Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOL

  • Type: Entry{Union{Int64, Vector}}
  • Units: -
  • Default: 20
act.ActorCoreRadHeatFlux.merge_wall

Merge dd.wall in mesh for the heat flux

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCoreRadHeatFlux.step

Step for discretization of the default wall mesh (dd.wall)

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.1
act.ActorCoreRadHeatFlux.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCoreTransport.model

Transport actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: FluxMatcher, EPEDProfiles, none
  • Default: FluxMatcher
act.ActorCoreTransport.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCosting.model

Costing model

  • Type: Switch{Symbol}
  • Units: -
  • Options: ARIES, Sheffield
  • Default: ARIES
act.ActorCosting.construction_start_year

Year that plant construction begins

  • Type: Entry{Int64}
  • Units: year
  • Default: 2024
act.ActorCosting.future_inflation_rate

Predicted average rate of future inflation

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.025
act.ActorCosting.plant_lifetime

Lifetime of the plant

  • Type: Entry{Int64}
  • Units: year
  • Default: 40
act.ActorCosting.availability

Availability fraction of the plant

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.8
act.ActorCosting.production_increase

Factor by which production of ReBCO multiplies

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorCosting.learning_rate

Learning rate for ReBCO technology production

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.85
act.ActorCostingARIES.land_space

Plant site space required

  • Type: Entry{Float64}
  • Units: acres
  • Default: 1000.0
act.ActorCostingARIES.building_volume

Volume of the tokmak building

  • Type: Entry{Float64}
  • Units: m^3
  • Default: 140000.0
act.ActorCostingARIES.interest_rate

Annual interest rate fraction of direct capital cost

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorCostingARIES.indirect_cost_rate

Indirect cost associated with construction, equipment, services, engineering construction management and owners cost

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.4
act.ActorCostingARIES.escalation_fraction

Yearly escalation fraction based on risk assessment

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorCostingARIES.blanket_lifetime

Lifetime of the blanket

  • Type: Entry{Float64}
  • Units: year
  • Default: 6.8
act.ActorCostingSheffield.construction_lead_time

Duration of construction

  • Type: Entry{Float64}
  • Units: year
  • Default: 8.0
act.ActorCostingSheffield.fixed_charge_rate

Constant dollar fixed charge rate

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.078
act.ActorCostingSheffield.capitalize_blanket

If true, include cost of 1st blanket in direct captial cost

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCostingSheffield.capitalize_divertor

If true, include cost of 1st divertor in direct captial cost

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCostingSheffield.divertor_fluence_lifetime

Divertor fluence over its lifetime

  • Type: Entry{Float64}
  • Units: MW*yr/m²
  • Default: 10.0
act.ActorCostingSheffield.blanket_fluence_lifetime

Blanket fluence over its lifetime

  • Type: Entry{Float64}
  • Units: MW*yr/m²
  • Default: 15.0
act.ActorCurrent.model

Current actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: SteadyStateCurrent, QED, none
  • Default: SteadyStateCurrent
act.ActorCurrent.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCurrent.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorCurrent.vloop_from

Take vloop from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule, controllers__ip
act.ActorDivertors.heat_flux_model

Divertor heat flux model

  • Type: Switch{Symbol}
  • Units: -
  • Options: lengyel, stangeby
  • Default: lengyel
act.ActorDivertors.impurities

Vector of impurity species

  • Type: Entry{Vector{Symbol}}
  • Units: -
  • Default: Symbol[]
act.ActorDivertors.impurities_fraction

Vector of impurity fractions

  • Type: Entry{Vector{Float64}}
  • Units: -
  • Default: Float64[]
act.ActorDivertors.heat_spread_factor

Heat flux expansion factor in the private flux region (eg. due to transport) should be >= 1.0

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorDivertors.thermal_power_extraction_efficiency

Fraction of thermal power that is carried out by the coolant at the divertor interface, rather than being lost in the surrounding strutures.

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorDivertors.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.Δt

Evolve for Δt

  • Type: Entry{Float64}
  • Units: s
act.ActorDynamicPlasma.Nt

Number of time steps during evolution

  • Type: Entry{Int64}
  • Units: -
act.ActorDynamicPlasma.evolve_transport

Evolve the transport

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_pedestal

Evolve the pedestal

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_hcd

Evolve the heating and current drive

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_current

Evolve the plasma current

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_equilibrium

Evolve the equilibrium

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_pf_active

Evolve the PF currents

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.ip_controller

Use controller to change v_loop to match desired Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.time_derivatives_sources

Include time-derivative sources

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPED.rho_nml

Defines rho at which the no man's land region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorEPED.rho_ped

Defines rho at which the pedestal region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorEPED.T_ratio_pedestal

Ratio of ion to electron temperatures (or rho at which to sample for that ratio, if negative; or rhonml-(rhoped-rho_nml) if 0.0)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPED.ped_factor

Pedestal height multiplier (width scaled by sqrt of this factor)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPED.only_powerlaw

EPED-NN uses power-law pedestal fit (without NN correction)

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPED.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorEPED.βn_from

Take βn from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium
act.ActorEPED.ne_ped_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorEPED.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorEPED.warn_nn_train_bounds

EPED-NN raises warnings if querying cases that are certainly outside of the training range

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPEDprofiles.T_shaping

Shaping coefficient for the temperature profile

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.8
act.ActorEPEDprofiles.ne_shaping

Shaping coefficient for the density profile

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.8
act.ActorEPEDprofiles.T_ratio_pedestal

Ion to electron temperature ratio in the pedestal

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPEDprofiles.T_ratio_core

Ion to electron temperature ratio in the core

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEquilibrium.model

Equilibrium actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: Solovev, CHEASE, TEQUILA
  • Default: TEQUILA
act.ActorEquilibrium.symmetrize

Force equilibrium up-down symmetry with respect to magnetic axis

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEquilibrium.j_p_from

Take j_tor and pressure profiles from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: equilibrium, core_profiles
  • Default: core_profiles
act.ActorEquilibrium.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorEquilibrium.vacuum_r0_b0_from

Take vacuumr0b0 from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: equilibrium, pulse_schedule
  • Default: pulse_schedule
act.ActorEquilibrium.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxCalculator.rho_transport

rho core transport grid

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorFluxCalculator.turbulence_model

Turbulence model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: TGLF, QLGYRO, none
  • Default: TGLF
act.ActorFluxCalculator.neoclassical_model

Neocalssical model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: neoclassical, none
  • Default: neoclassical
act.ActorFluxMatcher.rho_transport

ρ transport grid

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorFluxMatcher.evolve_Ti

Ion temperature :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: flux_match
act.ActorFluxMatcher.evolve_Te

Electron temperature :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: flux_match
act.ActorFluxMatcher.evolve_densities

Densities :fixed, or electron flux-match and rest match ne scale :flux_match, or Dict to specify which species are :flux_match, kept :fixed, used to enforce :quasi_neutrality, or scaled to :match_ne_scale

  • Type: Entry{Union{Symbol, AbstractDict}}
  • Units: -
  • Default: flux_match
act.ActorFluxMatcher.evolve_rotation

Rotation :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: fixed
act.ActorFluxMatcher.evolve_pedestal

Evolve the pedestal within the transport solver

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorFluxMatcher.find_widths

Runs turbulent transport actor TJLF finding widths after first iteration

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorFluxMatcher.max_iterations

Maximum optimizer iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 500
act.ActorFluxMatcher.optimizer_algorithm

Optimizing algorithm used for the flux matching

  • Type: Switch{Symbol}
  • Units: -
  • Options: anderson, newton, trust_region, simple, none
  • Default: anderson
act.ActorFluxMatcher.step_size

Step size for each algorithm iteration (note this has a different meaning for each algorithm)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorFluxMatcher.Δt

Evolve for Δt (Inf for steady state)

  • Type: Entry{Float64}
  • Units: s
  • Default: Inf
act.ActorFluxMatcher.save_input_tglf_folder

Save the intput.tglf files in designated folder at the last iteration

  • Type: Entry{String}
  • Units: -
  • Default: ``
act.ActorFluxMatcher.relax

Relaxation on the final solution

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorFluxMatcher.norms

Relative normalization of different channels

  • Type: Entry{Vector{Float64}}
  • Units: -
act.ActorFluxMatcher.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxMatcher.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxSwing.operate_oh_at_j_crit

If true it makes the OH operate at its current limit (within specified dd.requirements.coiljmargin`).

The flattop duration and maximum toroidal magnetic field follow from that. Otherwise we evaluate what is the current needed for dd.requirements.flattopduration, which may or may not exceed the OH critical current limit. If dd.requirements.flattopduration is not set, then operateohatjcrit is assumed. * Type: Entry{Bool} * Units: - * Default: false

act.ActorHCD.ec_model

EC source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: ECsimple, none
  • Default: ECsimple
act.ActorHCD.ic_model

IC source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: ICsimple, none
  • Default: ICsimple
act.ActorHCD.lh_model

LH source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: LHsimple, none
  • Default: LHsimple
act.ActorHCD.nb_model

NB source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: NBsimple, RABBIT, none
  • Default: NBsimple
act.ActorHCD.pellet_model

Pellet source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: Pelletsimple, none
  • Default: Pelletsimple
act.ActorHFSsizing.error_on_technology

Error if build stresses and current limits are not met

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorHFSsizing.error_on_performance

Error if requested Bt and flattop duration are not met

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorHFSsizing.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorHFSsizing.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorLFSsizing.maintenance

Scheme for installation/removal of in-vessel components

  • Type: Switch{Symbol}
  • Units: -
  • Options: vertical, horizontal, none
  • Default: none
act.ActorLFSsizing.tor_modularity

Number of toroidal modules of blanket normalized to number of TF coils

  • Type: Entry{Int64}
  • Units: -
  • Default: 2
act.ActorLFSsizing.pol_modularity

Number of poloidal modules of each toroidal blanket sector

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorLFSsizing.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorLFSsizing.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorNBI.model

NBI model

  • Type: Switch{Symbol}
  • Units: -
  • Options: simple, RABBIT
  • Default: simple
act.ActorNeoclassical.model

Neoclassical model to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: changhinton, neo, hirshmansigmar
  • Default: hirshmansigmar
act.ActorNeoclassical.rho_transport

rhotornorm values to compute neoclassical fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorNeutronics.N

Number of particles

  • Type: Entry{Int64}
  • Units: -
  • Default: 100000
act.ActorNeutronics.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFactive.green_model

Model used for the coils Green function calculations

  • Type: Switch{Symbol}
  • Units: -
  • Options: point, quad
  • Default: quad
act.ActorPFactive.update_equilibrium

Overwrite target equilibrium with the one that the coils can actually make

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFactive.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.symmetric

Force PF coils location to be up-down symmetric

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorPFdesign.update_equilibrium

Overwrite target equilibrium with the one that the coils can actually make

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.model

Coil placement strategy

  • Type: Switch{Symbol}
  • Units: -
  • Options: none, uniform, optimal
  • Default: optimal
act.ActorPFdesign.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorParticleHeatFlux.r

Vector of r at outermidplane

  • Type: Entry{Vector{Float64}}
  • Units: m
  • Default: Float64[]
act.ActorParticleHeatFlux.q

Vector of parallel power density at outer midplane

  • Type: Entry{Vector{Float64}}
  • Units: W m^-2
  • Default: Float64[]
act.ActorParticleHeatFlux.levels

If Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOL

  • Type: Entry{Union{Int64, Vector{Float64}}}
  • Units: -
  • Default: 20
act.ActorParticleHeatFlux.merge_wall

Merge dd.wall in mesh for the heat flux

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorParticleHeatFlux.step

Step for discretization of the default wall mesh (dd.wall)

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.1
act.ActorParticleHeatFlux.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPassiveStructures.wall_precision

Precision for making wall quadralaterals

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.1
act.ActorPassiveStructures.min_n_segments

Minimum number of quadralaterals

  • Type: Entry{Int64}
  • Units: -
  • Default: 15
act.ActorPassiveStructures.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPedestal.rho_nml

Defines rho at which the no man's land region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorPedestal.rho_ped

Defines rho at which the pedestal region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorPedestal.density_match

Matching density based on ne_ped or line averaged density

  • Type: Switch{Symbol}
  • Units: -
  • Options: ne_line, ne_ped
  • Default: ne_ped
act.ActorPedestal.model

Pedestal model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: EPED, WPED, auto, none
  • Default: EPED
act.ActorPedestal.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorPedestal.βn_from

Take βn from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium
act.ActorPedestal.ne_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorPedestal.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorPedestal.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPowerNeeds.model

Power plant electrical needs model

  • Type: Switch{Symbol}
  • Units: -
  • Options: thermal_power_fraction, EU_DEMO, FUSE
  • Default: FUSE
act.ActorPowerNeeds.thermal_power_fraction

Fraction of the gross electrical power generated by the thermal cycle (if model==:thermal_power_fraction)

  • Type: Entry{Float64}
  • Units: -
act.ActorPowerNeeds.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorQED.Δt

Evolve for Δt (Inf for steady state)

  • Type: Entry{Float64}
  • Units: s
  • Default: Inf
act.ActorQED.Nt

Number of time steps during evolution

  • Type: Entry{Int64}
  • Units: -
  • Default: 100
act.ActorQED.solve_for

Solve for specified Ip or Vloop

  • Type: Switch{Symbol}
  • Units: -
  • Options: ip, vloop
  • Default: ip
act.ActorQED.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
act.ActorQED.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorQED.vloop_from

Take vloop from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule, controllers__ip
act.ActorQLGYRO.model

Implementation of QLGYRO

  • Type: Switch{Symbol}
  • Units: -
  • Options: QLGYRO
  • Default: QLGYRO
act.ActorQLGYRO.ky

Max ky

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.6
act.ActorQLGYRO.nky

Number of ky modes

  • Type: Entry{Int64}
  • Units: -
  • Default: 16
act.ActorQLGYRO.cpu_per_ky

Number of cpus per ky

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorQLGYRO.kygrid_model

TGLF ky grid model

  • Type: Entry{Int64}
  • Units: -
  • Default: 0
act.ActorQLGYRO.sat_rule

Saturation rule

  • Type: Switch{Symbol}
  • Units: -
  • Options: sat1, sat2, sat3
  • Default: sat1
act.ActorQLGYRO.n_field

1:phi, 2:phi+apar, 3:phi+apar+bpar

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorQLGYRO.delta_t

CGYRO step size

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.005
act.ActorQLGYRO.max_time

Max simulation time (a/cs)

  • Type: Entry{Float64}
  • Units: -
  • Default: 100.0
act.ActorQLGYRO.rho_transport

rhotornorm values to compute QLGYRO fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorQLGYRO.lump_ions

Lumps the fuel species (D,T) as well as the impurities together

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorSimpleEC.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleIC.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleLH.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleNB.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSolovev.ngrid

Grid size (for R, Z follows proportionally to plasma elongation)

  • Type: Entry{Int64}
  • Units: -
  • Default: 129
act.ActorSolovev.qstar

Initial guess of kink safety factor

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.5
act.ActorSolovev.alpha

Initial guess of constant relating to pressure

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.0
act.ActorSolovev.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorSolovev.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStabilityLimits.models

Models used for checking plasma stability limits: [:densitylimits, :betalimits, :currentlimits, :defaultlimits, :unknown, :κcontrollability, :betamodel105, :q95gt2, :betabernard1983, :gwdensity, :betatuda1985, :betatroyon1985, :q08gt2, :betatroyon1984]

  • Type: Entry{Vector{Symbol}}
  • Units: -
  • Default: [:default_limits]
act.ActorStabilityLimits.raise_on_breach

Raise an error when one or more stability limits are breached

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorStationaryPlasma.max_iter

max number of transport-equilibrium iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 5
act.ActorStationaryPlasma.convergence_error

Convergence error threshold (relative change in current and pressure profiles)

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorStationaryPlasma.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStationaryPlasma.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorSteadyStateCurrent.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
act.ActorSteadyStateCurrent.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorStresses.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStresses.n_points

Number of grid points

  • Type: Entry{Int64}
  • Units: -
  • Default: 5
act.ActorTEQUILA.free_boundary

Convert fixed boundary equilibrium to free boundary one

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorTEQUILA.number_of_radial_grid_points

Number of TEQUILA radial grid points

  • Type: Entry{Int64}
  • Units: -
  • Default: 31
act.ActorTEQUILA.number_of_fourier_modes

Number of modes for Fourier decomposition

  • Type: Entry{Int64}
  • Units: -
  • Default: 8
act.ActorTEQUILA.number_of_MXH_harmonics

Number of Fourier harmonics in MXH representation of flux surfaces

  • Type: Entry{Int64}
  • Units: -
  • Default: 4
act.ActorTEQUILA.number_of_iterations

Number of TEQUILA iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 1000
act.ActorTEQUILA.relax

Relaxation on the Picard iterations

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.25
act.ActorTEQUILA.tolerance

Tolerance for terminating iterations

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.0001
act.ActorTEQUILA.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorTEQUILA.fixed_grid

Fix P and Jt on this rho grid

  • Type: Switch{Symbol}
  • Units: -
  • Options: poloidal, toroidal
  • Default: toroidal
act.ActorTEQUILA.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTEQUILA.debug

Print debug information withing TEQUILA solve

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTEQUILA.R

Psi R axis

  • Type: Entry{Vector{Float64}}
  • Units: m
act.ActorTEQUILA.Z

Psi Z axis

  • Type: Entry{Vector{Float64}}
  • Units: m
act.ActorTGLF.model

Implementation of TGLF

  • Type: Switch{Symbol}
  • Units: -
  • Options: TGLF, TGLFNN, TJLF
  • Default: TGLFNN
act.ActorTGLF.sat_rule

Saturation rule

  • Type: Switch{Symbol}
  • Units: -
  • Options: sat0, sat0quench, sat1, sat1geo, sat2, sat3
  • Default: sat1
act.ActorTGLF.electromagnetic

Electromagnetic or electrostatic

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorTGLF.user_specified_model

Use a user specified TGLF-NN model stored in TGLFNN/models

  • Type: Entry{String}
  • Units: -
  • Default: ``
act.ActorTGLF.rho_transport

rhotornorm values to compute tglf fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorTGLF.warn_nn_train_bounds

Raise warnings if querying cases that are certainly outside of the training range

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTGLF.custom_input_files

Sets up the input file that will be run with the custom input file as a mask

  • Type: Entry{Union{Vector{<:TGLFNN.InputTGLF}, Vector{<:TJLF.InputTJLF}}}
  • Units: -
act.ActorTGLF.lump_ions

Lumps the fuel species (D,T) as well as the impurities together

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorThermalPlant.model

Power plant heat cycle efficiency

  • Type: Switch{Symbol}
  • Units: -
  • Options: fixed_plant_efficiency, network, surogate
  • Default: surogate
act.ActorThermalPlant.fixed_plant_efficiency

Overall thermal cycle efficiency (if model=:fixed_plant_efficiency)

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.35
act.ActorThermalPlant.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorThermalPlant.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorVerticalStability.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorWPED.ped_to_core_fraction

Ratio of edge (@rho=0.9) to core stored energy [0.05 for L-mode, 0.3 for neg-T plasmas]

  • Type: Entry{Float64}
  • Units: -
act.ActorWPED.rho_ped

Defines rho at which the edge region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorWPED.ne_ped_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorWPED.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorWPED.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorWholeFacility.update_plasma

Run plasma related actors

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorWholeFacility.update_build

Optimize tokamak build

  • Type: Entry{Bool}
  • Units: -
  • Default: true
+
GitHub
act.ActorBalanceOfPlant.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorBlanket.minimum_first_wall_thickness

Minimum first wall thickness

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.02
act.ActorBlanket.blanket_multiplier

Neutron thermal power multiplier in blanket

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.2
act.ActorBlanket.thermal_power_extraction_efficiency

Fraction of thermal power that is carried out by the coolant at the blanket interface, rather than being lost in the surrounding strutures.

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorBlanket.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCHEASE.free_boundary

Convert fixed boundary equilibrium to free boundary one

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.clear_workdir

Clean the temporary workdir for CHEASE

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.rescale_eq_to_ip

Scale equilibrium to match Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCHEASE.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorCXbuild.rebuild_wall

Rebuild wall based on equilibrium

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCXbuild.n_points

Number of points used for cross-sectional outlines

  • Type: Entry{Int64}
  • Units: -
  • Default: 101
act.ActorCXbuild.divertor_size

Divertor size as fraction of plasma minor radius

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.4
act.ActorCXbuild.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCoreRadHeatFlux.N

Number of launched photons

  • Type: Entry{Int64}
  • Units: -
  • Default: 100000
act.ActorCoreRadHeatFlux.r

Vector of r at outermidplane

  • Type: Entry{Vector{Float64}}
  • Units: m
  • Default: Float64[]
act.ActorCoreRadHeatFlux.q

Vector of parallel power density at outer midplane

  • Type: Entry{Vector{Float64}}
  • Units: W m^-2
  • Default: Float64[]
act.ActorCoreRadHeatFlux.levels

If Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOL

  • Type: Entry{Union{Int64, Vector}}
  • Units: -
  • Default: 20
act.ActorCoreRadHeatFlux.merge_wall

Merge dd.wall in mesh for the heat flux

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCoreRadHeatFlux.step

Step for discretization of the default wall mesh (dd.wall)

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.1
act.ActorCoreRadHeatFlux.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCoreTransport.model

Transport actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: FluxMatcher, EPEDProfiles, none
  • Default: FluxMatcher
act.ActorCoreTransport.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCosting.model

Costing model

  • Type: Switch{Symbol}
  • Units: -
  • Options: ARIES, Sheffield
  • Default: ARIES
act.ActorCosting.construction_start_year

Year that plant construction begins

  • Type: Entry{Int64}
  • Units: year
  • Default: 2024
act.ActorCosting.future_inflation_rate

Predicted average rate of future inflation

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.025
act.ActorCosting.plant_lifetime

Lifetime of the plant

  • Type: Entry{Int64}
  • Units: year
  • Default: 40
act.ActorCosting.availability

Availability fraction of the plant

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.8
act.ActorCosting.production_increase

Factor by which production of ReBCO multiplies

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorCosting.learning_rate

Learning rate for ReBCO technology production

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.85
act.ActorCostingARIES.land_space

Plant site space required

  • Type: Entry{Float64}
  • Units: acres
  • Default: 1000.0
act.ActorCostingARIES.building_volume

Volume of the tokmak building

  • Type: Entry{Float64}
  • Units: m^3
  • Default: 140000.0
act.ActorCostingARIES.interest_rate

Annual interest rate fraction of direct capital cost

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorCostingARIES.indirect_cost_rate

Indirect cost associated with construction, equipment, services, engineering construction management and owners cost

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.4
act.ActorCostingARIES.escalation_fraction

Yearly escalation fraction based on risk assessment

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorCostingARIES.blanket_lifetime

Lifetime of the blanket

  • Type: Entry{Float64}
  • Units: year
  • Default: 6.8
act.ActorCostingSheffield.construction_lead_time

Duration of construction

  • Type: Entry{Float64}
  • Units: year
  • Default: 8.0
act.ActorCostingSheffield.fixed_charge_rate

Constant dollar fixed charge rate

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.078
act.ActorCostingSheffield.capitalize_blanket

If true, include cost of 1st blanket in direct captial cost

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCostingSheffield.capitalize_divertor

If true, include cost of 1st divertor in direct captial cost

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorCostingSheffield.divertor_fluence_lifetime

Divertor fluence over its lifetime

  • Type: Entry{Float64}
  • Units: MW*yr/m²
  • Default: 10.0
act.ActorCostingSheffield.blanket_fluence_lifetime

Blanket fluence over its lifetime

  • Type: Entry{Float64}
  • Units: MW*yr/m²
  • Default: 15.0
act.ActorCurrent.model

Current actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: SteadyStateCurrent, QED, none
  • Default: SteadyStateCurrent
act.ActorCurrent.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorCurrent.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorCurrent.vloop_from

Take vloop from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule, controllers__ip
act.ActorDivertors.heat_flux_model

Divertor heat flux model

  • Type: Switch{Symbol}
  • Units: -
  • Options: lengyel, stangeby
  • Default: lengyel
act.ActorDivertors.impurities

Vector of impurity species

  • Type: Entry{Vector{Symbol}}
  • Units: -
  • Default: Symbol[]
act.ActorDivertors.impurities_fraction

Vector of impurity fractions

  • Type: Entry{Vector{Float64}}
  • Units: -
  • Default: Float64[]
act.ActorDivertors.heat_spread_factor

Heat flux expansion factor in the private flux region (eg. due to transport) should be >= 1.0

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorDivertors.thermal_power_extraction_efficiency

Fraction of thermal power that is carried out by the coolant at the divertor interface, rather than being lost in the surrounding strutures.

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorDivertors.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.Δt

Evolve for Δt

  • Type: Entry{Float64}
  • Units: s
act.ActorDynamicPlasma.Nt

Number of time steps during evolution

  • Type: Entry{Int64}
  • Units: -
act.ActorDynamicPlasma.evolve_transport

Evolve the transport

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_pedestal

Evolve the pedestal

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_hcd

Evolve the heating and current drive

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_current

Evolve the plasma current

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_equilibrium

Evolve the equilibrium

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.evolve_pf_active

Evolve the PF currents

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorDynamicPlasma.ip_controller

Use controller to change v_loop to match desired Ip

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.time_derivatives_sources

Include time-derivative sources

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorDynamicPlasma.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPED.rho_nml

Defines rho at which the no man's land region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorEPED.rho_ped

Defines rho at which the pedestal region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorEPED.T_ratio_pedestal

Ratio of ion to electron temperatures (or rho at which to sample for that ratio, if negative; or rhonml-(rhoped-rho_nml) if 0.0)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPED.ped_factor

Pedestal height multiplier (width scaled by sqrt of this factor)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPED.only_powerlaw

EPED-NN uses power-law pedestal fit (without NN correction)

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPED.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorEPED.βn_from

Take βn from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium
act.ActorEPED.ne_ped_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorEPED.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorEPED.warn_nn_train_bounds

EPED-NN raises warnings if querying cases that are certainly outside of the training range

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEPEDprofiles.T_shaping

Shaping coefficient for the temperature profile

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.8
act.ActorEPEDprofiles.ne_shaping

Shaping coefficient for the density profile

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.8
act.ActorEPEDprofiles.T_ratio_pedestal

Ion to electron temperature ratio in the pedestal

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEPEDprofiles.T_ratio_core

Ion to electron temperature ratio in the core

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorEquilibrium.model

Equilibrium actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: Solovev, CHEASE, TEQUILA
  • Default: TEQUILA
act.ActorEquilibrium.symmetrize

Force equilibrium up-down symmetry with respect to magnetic axis

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorEquilibrium.j_p_from

Take j_tor and pressure profiles from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: equilibrium, core_profiles
  • Default: core_profiles
act.ActorEquilibrium.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorEquilibrium.vacuum_r0_b0_from

Take vacuumr0b0 from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: equilibrium, pulse_schedule
  • Default: pulse_schedule
act.ActorEquilibrium.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxCalculator.rho_transport

rho core transport grid

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorFluxCalculator.turbulence_model

Turbulence model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: TGLF, QLGYRO, none
  • Default: TGLF
act.ActorFluxCalculator.neoclassical_model

Neocalssical model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: neoclassical, none
  • Default: neoclassical
act.ActorFluxMatcher.rho_transport

ρ transport grid

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorFluxMatcher.evolve_Ti

Ion temperature :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: flux_match
act.ActorFluxMatcher.evolve_Te

Electron temperature :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: flux_match
act.ActorFluxMatcher.evolve_densities

Densities :fixed, or electron flux-match and rest match ne scale :flux_match, or Dict to specify which species are :flux_match, kept :fixed, used to enforce :quasi_neutrality, or scaled to :match_ne_scale

  • Type: Entry{Union{Symbol, AbstractDict}}
  • Units: -
  • Default: flux_match
act.ActorFluxMatcher.evolve_rotation

Rotation :flux_match or keep :fixed

  • Type: Switch{Symbol}
  • Units: -
  • Options: flux_match, fixed
  • Default: fixed
act.ActorFluxMatcher.evolve_pedestal

Evolve the pedestal within the transport solver

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorFluxMatcher.find_widths

Runs turbulent transport actor TJLF finding widths after first iteration

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorFluxMatcher.max_iterations

Maximum optimizer iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 500
act.ActorFluxMatcher.optimizer_algorithm

Optimizing algorithm used for the flux matching

  • Type: Switch{Symbol}
  • Units: -
  • Options: anderson, newton, trust_region, simple, none
  • Default: anderson
act.ActorFluxMatcher.step_size

Step size for each algorithm iteration (note this has a different meaning for each algorithm)

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorFluxMatcher.Δt

Evolve for Δt (Inf for steady state)

  • Type: Entry{Float64}
  • Units: s
  • Default: Inf
act.ActorFluxMatcher.save_input_tglf_folder

Save the intput.tglf files in designated folder at the last iteration

  • Type: Entry{String}
  • Units: -
  • Default: ``
act.ActorFluxMatcher.relax

Relaxation on the final solution

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorFluxMatcher.norms

Relative normalization of different channels

  • Type: Entry{Vector{Float64}}
  • Units: -
act.ActorFluxMatcher.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxMatcher.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorFluxSwing.operate_oh_at_j_crit

If true it makes the OH operate at its current limit (within specified dd.requirements.coiljmargin`).

The flattop duration and maximum toroidal magnetic field follow from that. Otherwise we evaluate what is the current needed for dd.requirements.flattopduration, which may or may not exceed the OH critical current limit. If dd.requirements.flattopduration is not set, then operateohatjcrit is assumed. * Type: Entry{Bool} * Units: - * Default: false

act.ActorHCD.ec_model

EC source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: ECsimple, none
  • Default: ECsimple
act.ActorHCD.ic_model

IC source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: ICsimple, none
  • Default: ICsimple
act.ActorHCD.lh_model

LH source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: LHsimple, none
  • Default: LHsimple
act.ActorHCD.nb_model

NB source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: NBsimple, RABBIT, none
  • Default: NBsimple
act.ActorHCD.pellet_model

Pellet source actor to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: Pelletsimple, none
  • Default: Pelletsimple
act.ActorHFSsizing.error_on_technology

Error if build stresses and current limits are not met

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorHFSsizing.error_on_performance

Error if requested Bt and flattop duration are not met

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorHFSsizing.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorHFSsizing.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorLFSsizing.maintenance

Scheme for installation/removal of in-vessel components

  • Type: Switch{Symbol}
  • Units: -
  • Options: vertical, horizontal, none
  • Default: none
act.ActorLFSsizing.tor_modularity

Number of toroidal modules of blanket normalized to number of TF coils

  • Type: Entry{Int64}
  • Units: -
  • Default: 2
act.ActorLFSsizing.pol_modularity

Number of poloidal modules of each toroidal blanket sector

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorLFSsizing.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorLFSsizing.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorNBI.model

NBI model

  • Type: Switch{Symbol}
  • Units: -
  • Options: simple, RABBIT
  • Default: simple
act.ActorNeoclassical.model

Neoclassical model to run

  • Type: Switch{Symbol}
  • Units: -
  • Options: changhinton, neo, hirshmansigmar
  • Default: hirshmansigmar
act.ActorNeoclassical.rho_transport

rhotornorm values to compute neoclassical fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorNeutronics.N

Number of particles

  • Type: Entry{Int64}
  • Units: -
  • Default: 100000
act.ActorNeutronics.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFactive.green_model

Model used for the coils Green function calculations

  • Type: Switch{Symbol}
  • Units: -
  • Options: point, quad
  • Default: quad
act.ActorPFactive.update_equilibrium

Overwrite target equilibrium with the one that the coils can actually make

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFactive.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.symmetric

Force PF coils location to be up-down symmetric

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorPFdesign.update_equilibrium

Overwrite target equilibrium with the one that the coils can actually make

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.model

Coil placement strategy

  • Type: Switch{Symbol}
  • Units: -
  • Options: none, uniform, optimal
  • Default: optimal
act.ActorPFdesign.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPFdesign.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorParticleHeatFlux.r

Vector of r at outermidplane

  • Type: Entry{Vector{Float64}}
  • Units: m
  • Default: Float64[]
act.ActorParticleHeatFlux.q

Vector of parallel power density at outer midplane

  • Type: Entry{Vector{Float64}}
  • Units: W m^-2
  • Default: Float64[]
act.ActorParticleHeatFlux.levels

If Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOL

  • Type: Entry{Union{Int64, Vector{Float64}}}
  • Units: -
  • Default: 20
act.ActorParticleHeatFlux.merge_wall

Merge dd.wall in mesh for the heat flux

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorParticleHeatFlux.step

Step for discretization of the default wall mesh (dd.wall)

  • Type: Entry{Float64}
  • Units: m
  • Default: 0.1
act.ActorParticleHeatFlux.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPassiveStructures.wall_precision

Precision for making wall quadralaterals

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.1
act.ActorPassiveStructures.min_n_segments

Minimum number of quadralaterals

  • Type: Entry{Int64}
  • Units: -
  • Default: 15
act.ActorPassiveStructures.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPedestal.rho_nml

Defines rho at which the no man's land region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorPedestal.rho_ped

Defines rho at which the pedestal region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorPedestal.density_match

Matching density based on ne_ped or line averaged density

  • Type: Switch{Symbol}
  • Units: -
  • Options: ne_line, ne_ped
  • Default: ne_ped
act.ActorPedestal.model

Pedestal model to use

  • Type: Switch{Symbol}
  • Units: -
  • Options: EPED, WPED, auto, none
  • Default: EPED
act.ActorPedestal.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorPedestal.βn_from

Take βn from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium
act.ActorPedestal.ne_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorPedestal.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorPedestal.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorPowerNeeds.model

Power plant electrical needs model

  • Type: Switch{Symbol}
  • Units: -
  • Options: thermal_power_fraction, EU_DEMO, FUSE
  • Default: FUSE
act.ActorPowerNeeds.thermal_power_fraction

Fraction of the gross electrical power generated by the thermal cycle (if model==:thermal_power_fraction)

  • Type: Entry{Float64}
  • Units: -
act.ActorPowerNeeds.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorQED.Δt

Evolve for Δt (Inf for steady state)

  • Type: Entry{Float64}
  • Units: s
  • Default: Inf
act.ActorQED.Nt

Number of time steps during evolution

  • Type: Entry{Int64}
  • Units: -
  • Default: 100
act.ActorQED.solve_for

Solve for specified Ip or Vloop

  • Type: Switch{Symbol}
  • Units: -
  • Options: ip, vloop
  • Default: ip
act.ActorQED.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
act.ActorQED.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorQED.vloop_from

Take vloop from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule, controllers__ip
act.ActorQLGYRO.model

Implementation of QLGYRO

  • Type: Switch{Symbol}
  • Units: -
  • Options: QLGYRO
  • Default: QLGYRO
act.ActorQLGYRO.ky

Max ky

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.6
act.ActorQLGYRO.nky

Number of ky modes

  • Type: Entry{Int64}
  • Units: -
  • Default: 16
act.ActorQLGYRO.cpu_per_ky

Number of cpus per ky

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorQLGYRO.kygrid_model

TGLF ky grid model

  • Type: Entry{Int64}
  • Units: -
  • Default: 0
act.ActorQLGYRO.sat_rule

Saturation rule

  • Type: Switch{Symbol}
  • Units: -
  • Options: sat1, sat2, sat3
  • Default: sat1
act.ActorQLGYRO.n_field

1:phi, 2:phi+apar, 3:phi+apar+bpar

  • Type: Entry{Int64}
  • Units: -
  • Default: 1
act.ActorQLGYRO.delta_t

CGYRO step size

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.005
act.ActorQLGYRO.max_time

Max simulation time (a/cs)

  • Type: Entry{Float64}
  • Units: -
  • Default: 100.0
act.ActorQLGYRO.rho_transport

rhotornorm values to compute QLGYRO fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorQLGYRO.lump_ions

Lumps the fuel species (D,T) as well as the impurities together

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorSimpleEC.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleIC.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleLH.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSimpleNB.ηcd_scale

Scaling factor for nominal current drive efficiency

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.0
act.ActorSolovev.ngrid

Grid size (for R, Z follows proportionally to plasma elongation)

  • Type: Entry{Int64}
  • Units: -
  • Default: 129
act.ActorSolovev.qstar

Initial guess of kink safety factor

  • Type: Entry{Float64}
  • Units: -
  • Default: 1.5
act.ActorSolovev.alpha

Initial guess of constant relating to pressure

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.0
act.ActorSolovev.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorSolovev.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStabilityLimits.models

Models used for checking plasma stability limits: [:densitylimits, :betalimits, :currentlimits, :defaultlimits, :unknown, :κcontrollability, :betamodel105, :q95gt2, :betabernard1983, :gwdensity, :betatuda1985, :betatroyon1985, :q08gt2, :betatroyon1984]

  • Type: Entry{Vector{Symbol}}
  • Units: -
  • Default: [:default_limits]
act.ActorStabilityLimits.raise_on_breach

Raise an error when one or more stability limits are breached

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorStationaryPlasma.max_iter

max number of transport-equilibrium iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 5
act.ActorStationaryPlasma.convergence_error

Convergence error threshold (relative change in current and pressure profiles)

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.05
act.ActorStationaryPlasma.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStationaryPlasma.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorSteadyStateCurrent.allow_floating_plasma_current

Zero loop voltage if non-inductive fraction exceeds 100% of the target Ip

  • Type: Entry{Bool}
  • Units: -
act.ActorSteadyStateCurrent.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorStresses.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorStresses.n_points

Number of grid points

  • Type: Entry{Int64}
  • Units: -
  • Default: 5
act.ActorTEQUILA.free_boundary

Convert fixed boundary equilibrium to free boundary one

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorTEQUILA.number_of_radial_grid_points

Number of TEQUILA radial grid points

  • Type: Entry{Int64}
  • Units: -
  • Default: 31
act.ActorTEQUILA.number_of_fourier_modes

Number of modes for Fourier decomposition

  • Type: Entry{Int64}
  • Units: -
  • Default: 8
act.ActorTEQUILA.number_of_MXH_harmonics

Number of Fourier harmonics in MXH representation of flux surfaces

  • Type: Entry{Int64}
  • Units: -
  • Default: 4
act.ActorTEQUILA.number_of_iterations

Number of TEQUILA iterations

  • Type: Entry{Int64}
  • Units: -
  • Default: 1000
act.ActorTEQUILA.relax

Relaxation on the Picard iterations

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.25
act.ActorTEQUILA.tolerance

Tolerance for terminating iterations

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.0001
act.ActorTEQUILA.ip_from

Take ip from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, equilibrium, pulse_schedule
act.ActorTEQUILA.fixed_grid

Fix P and Jt on this rho grid

  • Type: Switch{Symbol}
  • Units: -
  • Options: poloidal, toroidal
  • Default: toroidal
act.ActorTEQUILA.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTEQUILA.debug

Print debug information withing TEQUILA solve

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTEQUILA.R

Psi R axis

  • Type: Entry{Vector{Float64}}
  • Units: m
act.ActorTEQUILA.Z

Psi Z axis

  • Type: Entry{Vector{Float64}}
  • Units: m
act.ActorTGLF.model

Implementation of TGLF

  • Type: Switch{Symbol}
  • Units: -
  • Options: TGLF, TGLFNN, TJLF
  • Default: TGLFNN
act.ActorTGLF.sat_rule

Saturation rule

  • Type: Switch{Symbol}
  • Units: -
  • Options: sat0, sat0quench, sat1, sat1geo, sat2, sat3
  • Default: sat1
act.ActorTGLF.electromagnetic

Electromagnetic or electrostatic

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorTGLF.user_specified_model

Use a user specified TGLF-NN model stored in TGLFNN/models

  • Type: Entry{String}
  • Units: -
  • Default: ``
act.ActorTGLF.rho_transport

rhotornorm values to compute tglf fluxes on

  • Type: Entry{AbstractVector{Float64}}
  • Units: -
  • Default: 0.25:0.1:0.85
act.ActorTGLF.warn_nn_train_bounds

Raise warnings if querying cases that are certainly outside of the training range

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorTGLF.custom_input_files

Sets up the input file that will be run with the custom input file as a mask

  • Type: Entry{Union{Vector{<:TGLFNN.InputTGLF}, Vector{<:TJLF.InputTJLF}}}
  • Units: -
act.ActorTGLF.lump_ions

Lumps the fuel species (D,T) as well as the impurities together

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorThermalPlant.model

Power plant heat cycle efficiency

  • Type: Switch{Symbol}
  • Units: -
  • Options: fixed_plant_efficiency, network, surogate
  • Default: surogate
act.ActorThermalPlant.fixed_plant_efficiency

Overall thermal cycle efficiency (if model=:fixed_plant_efficiency)

  • Type: Entry{Float64}
  • Units: -
  • Default: 0.35
act.ActorThermalPlant.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorThermalPlant.verbose

Verbose

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorVerticalStability.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorWPED.ped_to_core_fraction

Ratio of edge (@rho=0.9) to core stored energy [0.05 for L-mode, 0.3 for neg-T plasmas]

  • Type: Entry{Float64}
  • Units: -
act.ActorWPED.rho_ped

Defines rho at which the edge region starts

  • Type: Entry{Float64}
  • Units: -
act.ActorWPED.ne_ped_from

Take ne_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorWPED.zeff_ped_from

Take zeff_ped from this IDS

  • Type: Switch{Symbol}
  • Units: -
  • Options: core_profiles, summary, pulse_schedule
act.ActorWPED.do_plot

Store the output dds of the workflow run

  • Type: Entry{Bool}
  • Units: -
  • Default: false
act.ActorWholeFacility.update_plasma

Run plasma related actors

  • Type: Entry{Bool}
  • Units: -
  • Default: true
act.ActorWholeFacility.update_build

Optimize tokamak build

  • Type: Entry{Bool}
  • Units: -
  • Default: true
diff --git a/dev/actors.html b/dev/actors.html index 1273fe50b..ddacddc3c 100644 --- a/dev/actors.html +++ b/dev/actors.html @@ -5,39 +5,39 @@ gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash});
GitHub

Physics and Engineering Actors

Physics and engineering actors are the fundamental building blocks of FUSE simulations:

  • Actors operate exclusively on IMAS.dd data
  • Actors functionality is controlled via act parameters
  • Actors can be combined into other actors

Fidelity hierarchy is enabled by concept of generic Vs specific actors

  • Generic actors define physics/component
  • Specific actors implement a specific model for that physics/component
  • For example:
    ActorEquilibrium  <--  generic
 ├─ ActorSolovev   <--  specific
-└─ ActorCHEASE    <--  specific
  • act.[ActorGeneric].model selects specific actor being used
  • All specific actors will expect data and fill the same enties in dd
    • IMAS.jl expressions are key to make this work seamlessly
  • Where possible actors should make use of generic actors and not hardcode use of specific actors

Balance plant (3 actors)

BalanceOfPlant

FUSE.ActorBalanceOfPlantMethod
ActorBalanceOfPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)

Balance of plant actor that estimates the net electrical power output by comparing the balance of plant electrical needs with the electricity generated from the thermal cycle.

Note

Stores data in dd.balance_of_plant

source
ActorBalanceOfPlant
+└─ ActorCHEASE    <--  specific
  • act.[ActorGeneric].model selects specific actor being used
  • All specific actors will expect data and fill the same enties in dd
    • IMAS.jl expressions are key to make this work seamlessly
  • Where possible actors should make use of generic actors and not hardcode use of specific actors

    • Balance plant (3 actors)

    BalanceOfPlant

    FUSE.ActorBalanceOfPlantMethod
    ActorBalanceOfPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Balance of plant actor that estimates the net electrical power output by comparing the balance of plant electrical needs with the electricity generated from the thermal cycle.

    Note

    Stores data in dd.balance_of_plant

    source
    ActorBalanceOfPlant
 └─ do_plot
-

    PowerNeeds

    FUSE.ActorPowerNeedsMethod
    ActorPowerNeeds(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Power needs actor that calculates the needed power to operate the plant

    • model = :thermal_power_fraction simply assumes that the power to balance a plant is a fraction of the gross electrical power generated by the thermal cycle.
    • model = :EU_DEMO subdivides the power plant electrical needs to [:cryostat, :tritium_handling, :pumping] using EU-DEMO numbers.
    • model = :FUSE subdivides power plant needs into subsystems and calculates their power needs.
    Note

    Stores data in dd.balance_of_plant.power_electric_plant_operation

    source
    ActorPowerNeeds
-├─ model
-├─ thermal_power_fraction
-└─ do_plot
-

    ThermalPlant

    FUSE.ActorThermalPlantMethod
    ActorThermalPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)
    Note

    Stores data in dd.balance_of_plant

    source
    ActorThermalPlant
+

    PowerNeeds

    FUSE.ActorPowerNeedsMethod
    ActorPowerNeeds(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Power needs actor that calculates the needed power to operate the plant

    • model = :thermal_power_fraction simply assumes that the power to balance a plant is a fraction of the gross electrical power generated by the thermal cycle.
    • model = :EU_DEMO subdivides the power plant electrical needs to [:cryostat, :tritium_handling, :pumping] using EU-DEMO numbers.
    • model = :FUSE subdivides power plant needs into subsystems and calculates their power needs.
    Note

    Stores data in dd.balance_of_plant.power_electric_plant_operation

    source
    ActorPowerNeeds
+├─ model
+├─ thermal_power_fraction
+└─ do_plot
+

    ThermalPlant

    FUSE.ActorThermalPlantMethod
    ActorThermalPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)
    Note

    Stores data in dd.balance_of_plant

    source
    ActorThermalPlant
 ├─ model
 ├─ fixed_plant_efficiency
 ├─ do_plot
 └─ verbose
-

    Build (5 actors)

    CXbuild

    FUSE.ActorCXbuildMethod
    ActorCXbuild(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Generates the 2D cross section of the tokamak build

    Note

    Manipulates data in dd.build

    source
    ActorCXbuild
+

    Build (5 actors)

    CXbuild

    FUSE.ActorCXbuildMethod
    ActorCXbuild(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Generates the 2D cross section of the tokamak build

    Note

    Manipulates data in dd.build

    source
    ActorCXbuild
 ├─ rebuild_wall
 ├─ n_points
 ├─ divertor_size
 └─ do_plot
-

    HFSsizing

    FUSE.ActorHFSsizingMethod
    ActorHFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Actor that resizes the High Field Side of the tokamak radial build

    • takes into account the OH maximum allowed superconductor current/Field
    • takes into account the stresses on the center stack
    Note

    Manipulates radial build information in dd.build.layer

    source
    ActorHFSsizing
-├─ error_on_technology
-├─ error_on_performance
-├─ do_plot
-└─ verbose
-

    FluxSwing

    FUSE.ActorFluxSwingMethod
    ActorFluxSwing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Depending on operate_oh_at_j_crit

    • true => Evaluate the OH current limits, and evaluate flattop duration from that.
    • false => Evaluate what are the currents needed for a given flattop duration. This may or may not exceed the OH current limits.

    OH flux consumption based on:

    • rampup estimate based on Ejima coefficient
    • flattop consumption
    • vertical field from PF coils
    Note

    Stores data in dd.build.flux_swing, dd.build.tf, and dd.build.oh

    source
    ActorFluxSwing
+

    HFSsizing

    FUSE.ActorHFSsizingMethod
    ActorHFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Actor that resizes the High Field Side of the tokamak radial build

    • takes into account the OH maximum allowed superconductor current/Field
    • takes into account the stresses on the center stack
    Note

    Manipulates radial build information in dd.build.layer

    source
    ActorHFSsizing
+├─ error_on_technology
+├─ error_on_performance
+├─ do_plot
+└─ verbose
+

    FluxSwing

    FUSE.ActorFluxSwingMethod
    ActorFluxSwing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Depending on operate_oh_at_j_crit

    • true => Evaluate the OH current limits, and evaluate flattop duration from that.
    • false => Evaluate what are the currents needed for a given flattop duration. This may or may not exceed the OH current limits.

    OH flux consumption based on:

    • rampup estimate based on Ejima coefficient
    • flattop consumption
    • vertical field from PF coils
    Note

    Stores data in dd.build.flux_swing, dd.build.tf, and dd.build.oh

    source
    ActorFluxSwing
 └─ operate_oh_at_j_crit
-

    LFSsizing

    FUSE.ActorLFSsizingMethod
    ActorLFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Actor that resizes the Low Field Side of the tokamak radial build

    • Places TF outer leg at radius required to meet the dd.build.tf.ripple requirement
    • Other low-field side layers are scaled proportionally
    Note

    Manipulates radial build information in dd.build.layer

    source
    ActorLFSsizing
+

    LFSsizing

    FUSE.ActorLFSsizingMethod
    ActorLFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Actor that resizes the Low Field Side of the tokamak radial build

    • Places TF outer leg at radius required to meet the dd.build.tf.ripple requirement
    • Other low-field side layers are scaled proportionally
    Note

    Manipulates radial build information in dd.build.layer

    source
    ActorLFSsizing
 ├─ maintenance
 ├─ tor_modularity
 ├─ pol_modularity
 ├─ do_plot
 └─ verbose
-

    Stresses

    FUSE.ActorStressesMethod
    ActorStresses(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates mechanical stresses on the center stack

    Note

    Stores data in dd.solid_mechanics

    source
    ActorStresses
+

    Stresses

    FUSE.ActorStressesMethod
    ActorStresses(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates mechanical stresses on the center stack

    Note

    Stores data in dd.solid_mechanics

    source
    ActorStresses
 ├─ do_plot
 └─ n_points
-

    Compound (3 actors)

    DynamicPlasma

    ActorDynamicPlasma
+

    Compound (3 actors)

    DynamicPlasma

    ActorDynamicPlasma
 ├─ Δt  [s]
 ├─ Nt
 ├─ evolve_transport
@@ -49,15 +49,15 @@
 ├─ ip_controller
 ├─ time_derivatives_sources
 └─ verbose
-

    StationaryPlasma

    FUSE.ActorStationaryPlasmaMethod
    ActorStationaryPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compound actor that runs the following actors in succesion:

    • ActorCurrent
    • ActorHCD
    • ActorCoreTransport
    • ActorEquilibrium
    Note

    Stores data in dd.equilibrium, dd.core_profiles, dd.core_sources, dd.core_transport

    source
    ActorStationaryPlasma
+

    StationaryPlasma

    FUSE.ActorStationaryPlasmaMethod
    ActorStationaryPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compound actor that runs the following actors in succesion:

    • ActorCurrent
    • ActorHCD
    • ActorCoreTransport
    • ActorEquilibrium
    Note

    Stores data in dd.equilibrium, dd.core_profiles, dd.core_sources, dd.core_transport

    source
    ActorStationaryPlasma
 ├─ max_iter
 ├─ convergence_error
 ├─ do_plot
 └─ verbose
-

    WholeFacility

    FUSE.ActorWholeFacilityMethod
    ActorWholeFacility(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compound actor that runs all the physics, engineering and costing actors needed to model the whole plant:

    • ActorStationaryPlasma
    • ActorStabilityLimits
    • ActorHFSsizing
    • ActorLFSsizing
    • ActorCXbuild
    • ActorFluxSwing
    • ActorStresses
    • ActorPFdesign
    • ActorPFactive
    • ActorPassiveStructures
    • ActorVerticalStability
    • ActorNeutronics
    • ActorBlanket
    • ActorDivertors
    • ActorBalanceOfPlant
    • ActorCosting
    Note

    Stores data in dd

    source
    ActorWholeFacility
+

    WholeFacility

    FUSE.ActorWholeFacilityMethod
    ActorWholeFacility(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compound actor that runs all the physics, engineering and costing actors needed to model the whole plant:

    • ActorStationaryPlasma
    • ActorStabilityLimits
    • ActorHFSsizing
    • ActorLFSsizing
    • ActorCXbuild
    • ActorFluxSwing
    • ActorStresses
    • ActorPFdesign
    • ActorPFactive
    • ActorPassiveStructures
    • ActorVerticalStability
    • ActorNeutronics
    • ActorBlanket
    • ActorDivertors
    • ActorBalanceOfPlant
    • ActorCosting
    Note

    Stores data in dd

    source
    ActorWholeFacility
 ├─ update_plasma
 └─ update_build
-

    Costing (3 actors)

    Costing

    FUSE.ActorCostingMethod
    ActorCosting(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the cost of building, operating, and recommission the fusion power plant.

    Note

    Stores data in dd.costing

    source
    ActorCosting
+

    Costing (3 actors)

    Costing

    FUSE.ActorCostingMethod
    ActorCosting(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the cost of building, operating, and recommission the fusion power plant.

    Note

    Stores data in dd.costing

    source
    ActorCosting
 ├─ model
 ├─ construction_start_year  [year]
 ├─ future_inflation_rate
@@ -65,63 +65,63 @@
 ├─ availability
 ├─ production_increase
 └─ learning_rate
-

    CostingARIES

    FUSE.ActorCostingARIESMethod
    ActorCostingARIES(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates costing based on ARIES cost account documentation https://cer.ucsd.edu/_files/publications/UCSD-CER-13-01.pdf

    Note

    Stores data in dd.costing

    source
    ActorCostingARIES
+

    CostingARIES

    FUSE.ActorCostingARIESMethod
    ActorCostingARIES(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates costing based on ARIES cost account documentation https://cer.ucsd.edu/_files/publications/UCSD-CER-13-01.pdf

    Note

    Stores data in dd.costing

    source
    ActorCostingARIES
 ├─ land_space  [acres]
 ├─ building_volume  [m³]
 ├─ interest_rate
 ├─ indirect_cost_rate
 ├─ escalation_fraction
 └─ blanket_lifetime  [year]
-

    CostingSheffield

    FUSE.ActorCostingSheffieldMethod
    ActorCostingSheffield(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates costing based on Sheffield and Milora, FS&T 70 (2016)

    Note

    Stores data in dd.costing

    source
    ActorCostingSheffield
+

    CostingSheffield

    FUSE.ActorCostingSheffieldMethod
    ActorCostingSheffield(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates costing based on Sheffield and Milora, FS&T 70 (2016)

    Note

    Stores data in dd.costing

    source
    ActorCostingSheffield
 ├─ construction_lead_time  [year]
 ├─ fixed_charge_rate
 ├─ capitalize_blanket
 ├─ capitalize_divertor
 ├─ divertor_fluence_lifetime  [MW*yr/m²]
 └─ blanket_fluence_lifetime  [MW*yr/m²]
-

    Current (3 actors)

    Current

    FUSE.ActorCurrentMethod
    ActorCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple ohmic current evolution actors

    • Sets the j_ohmic, j_tor, j_total under dd.core_profiles.profiles_1d[]
    • Sets j_parallel in dd.equilibrium.time_slice[].profiles_1d
    • Updates bootstrap and ohmic parallel current and heating sources in dd.core_sources
    source
    ActorCurrent
+

    Current (3 actors)

    Current

    FUSE.ActorCurrentMethod
    ActorCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple ohmic current evolution actors

    • Sets the j_ohmic, j_tor, j_total under dd.core_profiles.profiles_1d[]
    • Sets j_parallel in dd.equilibrium.time_slice[].profiles_1d
    • Updates bootstrap and ohmic parallel current and heating sources in dd.core_sources
    source
    ActorCurrent
 ├─ model
 ├─ allow_floating_plasma_current
 ├─ ip_from
 └─ vloop_from

    QED

    FUSE.ActorQEDMethod
    ActorQED(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evolves the plasma current using the QED current diffusion solver.

    Note

    This actor operates at "dd.global_time", any time advance must be done outside of the actor

    IMAS.new_timeslice!(dd, dd.global_time + Δt)
 dd.global_time += Δt
-ActorQED(dd, act)
    Note

    Stores data in dd.core_profiles.profiles_1d[].j_ohmic

    source
    ActorQED
+ActorQED(dd, act)
    Note

    Stores data in dd.core_profiles.profiles_1d[].j_ohmic

    source
    ActorQED
 ├─ Δt  [s]
 ├─ Nt
 ├─ solve_for
 ├─ allow_floating_plasma_current
 ├─ ip_from
 └─ vloop_from
-

    SteadyStateCurrent

    FUSE.ActorSteadyStateCurrentMethod
    ActorSteadyStateCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evolves the ohmic current to steady state using the conductivity from dd.core_profiles

    Note

    Stores data in dd.core_profiles.profiles_1d[].j_ohmic

    source
    ActorSteadyStateCurrent
+

    SteadyStateCurrent

    FUSE.ActorSteadyStateCurrentMethod
    ActorSteadyStateCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evolves the ohmic current to steady state using the conductivity from dd.core_profiles

    Note

    Stores data in dd.core_profiles.profiles_1d[].j_ohmic

    source
    ActorSteadyStateCurrent
 ├─ allow_floating_plasma_current
 └─ ip_from
-

    Divertors (1 actors)

    Divertors

    FUSE.ActorDivertorsMethod
    ActorDivertors(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates divertor loading and deposited power

    Note

    Stores data in dd.divertors

    source
    ActorDivertors
+

    Divertors (1 actors)

    Divertors

    FUSE.ActorDivertorsMethod
    ActorDivertors(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates divertor loading and deposited power

    Note

    Stores data in dd.divertors

    source
    ActorDivertors
 ├─ heat_flux_model
 ├─ impurities
 ├─ impurities_fraction
 ├─ heat_spread_factor
 ├─ thermal_power_extraction_efficiency
 └─ verbose
-

    Equilibrium (4 actors)

    Equilibrium

    FUSE.ActorEquilibriumMethod
    ActorEquilibrium(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple equilibrium actors

    source
    ActorEquilibrium
-├─ model
-├─ symmetrize
-├─ j_p_from
-├─ ip_from
-├─ vacuum_r0_b0_from
-└─ do_plot
-

    CHEASE

    FUSE.ActorCHEASEMethod
    ActorCHEASE(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs the Fixed boundary equilibrium solver CHEASE

    source
    ActorCHEASE
+

    Equilibrium (4 actors)

    Equilibrium

    FUSE.ActorEquilibriumMethod
    ActorEquilibrium(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple equilibrium actors

    source
    ActorEquilibrium
+├─ model
+├─ symmetrize
+├─ j_p_from
+├─ ip_from
+├─ vacuum_r0_b0_from
+└─ do_plot
+

    CHEASE

    FUSE.ActorCHEASEMethod
    ActorCHEASE(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs the Fixed boundary equilibrium solver CHEASE

    source
    ActorCHEASE
 ├─ free_boundary
 ├─ clear_workdir
 ├─ rescale_eq_to_ip
 └─ ip_from
-

    Solovev

    FUSE.ActorSolovevMethod
    ActorSolovev(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Solovev equilibrium actor, based on: “One size fits all” analytic solutions to the Grad–Shafranov equation Phys. Plasmas 17, 032502 (2010); https://doi.org/10.1063/1.3328818

    source
    ActorSolovev
+

    Solovev

    FUSE.ActorSolovevMethod
    ActorSolovev(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Solovev equilibrium actor, based on: “One size fits all” analytic solutions to the Grad–Shafranov equation Phys. Plasmas 17, 032502 (2010); https://doi.org/10.1063/1.3328818

    source
    ActorSolovev
 ├─ ngrid
 ├─ qstar
 ├─ alpha
 ├─ ip_from
 └─ verbose
-

    TEQUILA

    FUSE.ActorTEQUILAMethod
    ActorTEQUILA(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs the Fixed boundary equilibrium solver TEQUILA

    source
    ActorTEQUILA
+

    TEQUILA

    FUSE.ActorTEQUILAMethod
    ActorTEQUILA(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs the Fixed boundary equilibrium solver TEQUILA

    source
    ActorTEQUILA
 ├─ free_boundary
 ├─ number_of_radial_grid_points
 ├─ number_of_fourier_modes
@@ -135,28 +135,28 @@
 ├─ debug
 ├─ R  [m]
 └─ Z  [m]
-

    Hcd (5 actors)

    HCD

    FUSE.ActorHCDMethod
    ActorHCD(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run HCD actors

    source
    ActorHCD
-├─ ec_model
-├─ ic_model
-├─ lh_model
-├─ nb_model
-└─ pellet_model
-

    SimpleEC

    FUSE.ActorSimpleECMethod
    ActorSimpleEC(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the EC electron energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.ec_launchers, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleEC
+

    Hcd (5 actors)

    HCD

    FUSE.ActorHCDMethod
    ActorHCD(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run HCD actors

    source
    ActorHCD
+├─ ec_model
+├─ ic_model
+├─ lh_model
+├─ nb_model
+└─ pellet_model
+

    SimpleEC

    FUSE.ActorSimpleECMethod
    ActorSimpleEC(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the EC electron energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.ec_launchers, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleEC
 └─ ηcd_scale
-

    SimpleIC

    FUSE.ActorSimpleICMethod
    ActorSimpleIC(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the ion-cyclotron electron/ion energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.ic_antennas, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleIC
+

    SimpleIC

    FUSE.ActorSimpleICMethod
    ActorSimpleIC(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the ion-cyclotron electron/ion energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.ic_antennas, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleIC
 └─ ηcd_scale
-

    SimpleLH

    FUSE.ActorSimpleLHMethod
    ActorSimpleLH(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the Lower-hybrid electron energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.lh_antennas, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleLH
+

    SimpleLH

    FUSE.ActorSimpleLHMethod
    ActorSimpleLH(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the Lower-hybrid electron energy deposition and current drive as a gaussian.

    NOTE: Current drive efficiency from GASC, based on "G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'"

    Note

    Reads data in dd.lh_antennas, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimpleLH
 └─ ηcd_scale
-

    SimplePellet

    FUSE.ActorSimplePelletMethod
    ActorSimplePellet(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the Pellet particle deposition

    Note

    Reads data in dd.pellet_launchers, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimplePellet
-

    Nuclear (2 actors)

    Blanket

    FUSE.ActorBlanketMethod
    ActorBlanket(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates blankets tritium breeding ratio (TBR), heat deposition, and neutron leakage

    Note

    Stores data in dd.blanket

    source
    ActorBlanket
+

    SimplePellet

    FUSE.ActorSimplePelletMethod
    ActorSimplePellet(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the Pellet particle deposition

    Note

    Reads data in dd.pellet_launchers, dd.pulse_schedule and stores data in dd.core_sources

    source
    ActorSimplePellet
+

    Nuclear (2 actors)

    Blanket

    FUSE.ActorBlanketMethod
    ActorBlanket(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates blankets tritium breeding ratio (TBR), heat deposition, and neutron leakage

    Note

    Stores data in dd.blanket

    source
    ActorBlanket
 ├─ minimum_first_wall_thickness  [m]
 ├─ blanket_multiplier
 ├─ thermal_power_extraction_efficiency
 └─ verbose
-

    Neutronics

    FUSE.ActorNeutronicsMethod
    ActorNeutronics(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the neutron wall loading

    Note

    Stores data in dd.neutronics

    source
    ActorNeutronics
+

    Neutronics

    FUSE.ActorNeutronicsMethod
    ActorNeutronics(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Estimates the neutron wall loading

    Note

    Stores data in dd.neutronics

    source
    ActorNeutronics
 ├─ N
 └─ do_plot
-

    Pedestal (3 actors)

    Pedestal

    FUSE.ActorPedestalMethod
    ActorPedestal(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the pedestal boundary condition (height and width)

    source
    ActorPedestal
+

    Pedestal (3 actors)

    Pedestal

    FUSE.ActorPedestalMethod
    ActorPedestal(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the pedestal boundary condition (height and width)

    source
    ActorPedestal
 ├─ rho_nml
 ├─ rho_ped
 ├─ density_match
@@ -166,7 +166,7 @@
 ├─ ne_from
 ├─ zeff_ped_from
 └─ do_plot
-

    EPED

    FUSE.ActorEPEDMethod
    ActorEPED(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the pedestal boundary condition (height and width)

    source
    ActorEPED
+

    EPED

    FUSE.ActorEPEDMethod
    ActorEPED(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the pedestal boundary condition (height and width)

    source
    ActorEPED
 ├─ rho_nml
 ├─ rho_ped
 ├─ T_ratio_pedestal
@@ -177,44 +177,44 @@
 ├─ ne_ped_from
 ├─ zeff_ped_from
 └─ warn_nn_train_bounds
-

    WPED

    FUSE.ActorWPEDMethod
    ActorWPED(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Finds the temperature profile at the edge to match the pedtocorefraction of stored energy set in par.pedtocorefraction

    source
    ActorWPED
+

    WPED

    FUSE.ActorWPEDMethod
    ActorWPED(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Finds the temperature profile at the edge to match the pedtocorefraction of stored energy set in par.pedtocorefraction

    source
    ActorWPED
 ├─ ped_to_core_fraction
 ├─ rho_ped
 ├─ ne_ped_from
 ├─ zeff_ped_from
 └─ do_plot
-

    Pf (3 actors)

    PFdesign

    FUSE.ActorPFdesignMethod
    ActorPFdesign(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Optimize PF coil locations to achieve desired equilibrium

    Note

    Manupulates data in dd.pf_active

    source
    ActorPFdesign
-├─ symmetric
-├─ update_equilibrium
-├─ model
-├─ do_plot
-└─ verbose
-

    PFactive

    FUSE.ActorPFactiveMethod
    ActorPFactive(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Finds the optimal coil currents to match the equilibrium boundary shape

    Note

    Manupulates data in dd.pf_active

    source
    ActorPFactive
+

    Pf (3 actors)

    PFdesign

    FUSE.ActorPFdesignMethod
    ActorPFdesign(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Optimize PF coil locations to achieve desired equilibrium

    Note

    Manupulates data in dd.pf_active

    source
    ActorPFdesign
+├─ symmetric
+├─ update_equilibrium
+├─ model
+├─ do_plot
+└─ verbose
+

    PFactive

    FUSE.ActorPFactiveMethod
    ActorPFactive(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Finds the optimal coil currents to match the equilibrium boundary shape

    Note

    Manupulates data in dd.pf_active

    source
    ActorPFactive
 ├─ green_model
 ├─ update_equilibrium
 └─ do_plot
-

    PassiveStructures

    FUSE.ActorPassiveStructuresMethod
    ActorPassiveStructures(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Populates pf_passive structures

    source
    ActorPassiveStructures
+

    PassiveStructures

    FUSE.ActorPassiveStructuresMethod
    ActorPassiveStructures(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Populates pf_passive structures

    source
    ActorPassiveStructures
 ├─ wall_precision
 ├─ min_n_segments
 └─ do_plot
-

    Stability (2 actors)

    StabilityLimits

    FUSE.ActorStabilityLimitsMethod
    ActorStabilityLimits(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs all the limit actors

    source
    ActorStabilityLimits
+

    Stability (2 actors)

    StabilityLimits

    FUSE.ActorStabilityLimitsMethod
    ActorStabilityLimits(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Runs all the limit actors

    source
    ActorStabilityLimits
 ├─ models
 └─ raise_on_breach
-

    VerticalStability

    FUSE.ActorVerticalStabilityMethod
    ActorVerticalStability(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compute vertical stability metrics

    source
    ActorVerticalStability
+

    VerticalStability

    FUSE.ActorVerticalStabilityMethod
    ActorVerticalStability(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Compute vertical stability metrics

    source
    ActorVerticalStability
 └─ do_plot
-

    Transport (7 actors)

    CoreTransport

    FUSE.ActorCoreTransportMethod
    ActorCoreTransport(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple core transport actors

    source
    ActorCoreTransport
+

    Transport (7 actors)

    CoreTransport

    FUSE.ActorCoreTransportMethod
    ActorCoreTransport(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple core transport actors

    source
    ActorCoreTransport
 ├─ model
 └─ do_plot
-

    EPEDprofiles

    FUSE.ActorEPEDprofilesMethod
    ActorEPEDprofiles(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Updates pedestal height and width and blends with core profiles that are defined by shaping factors.

    Does not change on-axis values of plasma profiles.

    source
    ActorEPEDprofiles
+

    EPEDprofiles

    FUSE.ActorEPEDprofilesMethod
    ActorEPEDprofiles(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Updates pedestal height and width and blends with core profiles that are defined by shaping factors.

    Does not change on-axis values of plasma profiles.

    source
    ActorEPEDprofiles
 ├─ T_shaping
 ├─ ne_shaping
 ├─ T_ratio_pedestal
 └─ T_ratio_core
-

    FluxCalculator

    FUSE.ActorFluxCalculatorMethod
    ActorFluxCalculator(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple transport model actors

    source
    ActorFluxCalculator
+

    FluxCalculator

    FUSE.ActorFluxCalculatorMethod
    ActorFluxCalculator(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Provides a common interface to run multiple transport model actors

    source
    ActorFluxCalculator
 ├─ rho_transport
 ├─ turbulence_model
 └─ neoclassical_model
-

    FluxMatcher

    FUSE.ActorFluxMatcherMethod
    ActorFluxMatcher(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evalutes the transport fluxes and source fluxes and minimizes the flux_match error

    source
    ActorFluxMatcher
+

    FluxMatcher

    FUSE.ActorFluxMatcherMethod
    ActorFluxMatcher(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evalutes the transport fluxes and source fluxes and minimizes the flux_match error

    source
    ActorFluxMatcher
 ├─ rho_transport
 ├─ evolve_Ti
 ├─ evolve_Te
@@ -231,22 +231,22 @@
 ├─ norms
 ├─ do_plot
 └─ verbose
-

    Neoclassical

    FUSE.ActorNeoclassicalMethod
    ActorNeoclassical(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the neoclassical transport fluxes

    source
    ActorNeoclassical
+

    Neoclassical

    FUSE.ActorNeoclassicalMethod
    ActorNeoclassical(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the neoclassical transport fluxes

    source
    ActorNeoclassical
 ├─ model
 └─ rho_transport
-

    QLGYRO

    FUSE.ActorQLGYROMethod
    ActorQLGYRO(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the QLGYRO predicted turbulence

    source
    ActorQLGYRO
-├─ model
-├─ ky
-├─ nky
-├─ cpu_per_ky
-├─ kygrid_model
-├─ sat_rule
-├─ n_field
-├─ delta_t
-├─ max_time
-├─ rho_transport
-└─ lump_ions
-

    TGLF

    FUSE.ActorTGLFMethod
    ActorTGLF(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the TGLF predicted turbulence

    source
    ActorTGLF
+

    QLGYRO

    FUSE.ActorQLGYROMethod
    ActorQLGYRO(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the QLGYRO predicted turbulence

    source
    ActorQLGYRO
+├─ model
+├─ ky
+├─ nky
+├─ cpu_per_ky
+├─ kygrid_model
+├─ sat_rule
+├─ n_field
+├─ delta_t
+├─ max_time
+├─ rho_transport
+└─ lump_ions
+

    TGLF

    FUSE.ActorTGLFMethod
    ActorTGLF(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Evaluates the TGLF predicted turbulence

    source
    ActorTGLF
 ├─ model
 ├─ sat_rule
 ├─ electromagnetic
@@ -255,7 +255,7 @@
 ├─ warn_nn_train_bounds
 ├─ custom_input_files
 └─ lump_ions
-

    Wall loading (2 actors)

    CoreRadHeatFlux

    FUSE.ActorCoreRadHeatFluxMethod
    ActorCoreRadHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Computes the heat flux on the wall due to the core radiation

    source
    ActorCoreRadHeatFlux
+

    Wall loading (2 actors)

    CoreRadHeatFlux

    FUSE.ActorCoreRadHeatFluxMethod
    ActorCoreRadHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Computes the heat flux on the wall due to the core radiation

    source
    ActorCoreRadHeatFlux
 ├─ N
 ├─ r  [m]
 ├─ q  [W m⁻²]
@@ -263,11 +263,11 @@
 ├─ merge_wall
 ├─ step  [m]
 └─ do_plot
-

    ParticleHeatFlux

    FUSE.ActorParticleHeatFluxMethod
    ActorParticleHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Computes the heat flux on the wall due to the charged particles

    source
    ActorParticleHeatFlux
-├─ r  [m]
-├─ q  [W m⁻²]
-├─ levels
-├─ merge_wall
-├─ step  [m]
-└─ do_plot
-
    +

    ParticleHeatFlux

    FUSE.ActorParticleHeatFluxMethod
    ActorParticleHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)

    Computes the heat flux on the wall due to the charged particles

    source
    ActorParticleHeatFlux
+├─ r  [m]
+├─ q  [W m⁻²]
+├─ levels
+├─ merge_wall
+├─ step  [m]
+└─ do_plot
+
    diff --git a/dev/cases.html b/dev/cases.html index 3bed80e1f..a9fe1ac0f 100644 --- a/dev/cases.html +++ b/dev/cases.html @@ -3,11 +3,11 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub

    Use cases

    FUSE comes with a set of pre-cookes used cases. The case_parameters(:use_case, ...) method returns the ini and act parameters for that specific use_case. These ini and act can then be further customized before running a FUSE simulation.

    To create your own case and add them to FUSE/cases copy one of the other cases as a template and change the ini/act parameters inside. A handy way of generating the ini code from your_ini that you created in a notebook or elsewhere is to call the function FUSE.case_parameter_creation_from_ini(your_ini) which will return a nicely formatted code snippet.

    Tip!

    Click on the Source button of each use case to see how each is setup

    ARC

    CAT

    D3D

    FUSE.case_parametersMethod
    case_parameters(:D3D;
+
    GitHub
    Use cases
    FUSE comes with a set of pre-cookes used cases. The case_parameters(:use_case, ...) method returns the ini and act parameters for that specific use_case. These ini and act can then be further customized before running a FUSE simulation.
    To create your own case and add them to FUSE/cases copy one of the other cases as a template and change the ini/act parameters inside. A handy way of generating the ini code from your_ini that you created in a notebook or elsewhere is to call the function FUSE.case_parameter_creation_from_ini(your_ini) which will return a nicely formatted code snippet.
    Tip!
    Click on the Source button of each use case to see how each is setup
    ARC
    CAT
    D3D
    FUSE.case_parametersMethod
    case_parameters(:D3D;
     scenario::Union{Symbol,AbstractString}=:default,
-    use_scenario_sources::Bool=typeof(scenario)
    DIII-D
    Scenario keyword can be:
    • :default 133221
    • :H_mode a prototypical H_mode
    • :L_mode a prototypical L_mode
    • a user defined string pointing to a ODS on file saved in JSON format
    use_scenario_sources keywods says whether core_sources will be taken from scenario or not
    source
    DTT
    EXCITE
    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:EXCITE}})::Tuple{ParametersAllInits,ParametersAllActors}
    GA EXCITE design
    source
    FIRST
    FPP
    HDB5
    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:HDB5}}; tokamak::Union{String,Symbol}=:any, case=missing, database_case=missing)
    For description of cases/variables see https://osf.io/593q6/
    source
    ITER
    FUSE.case_parametersMethod
    case_parameters(
+    use_scenario_sources::Bool=typeof(scenario)
    DIII-D
    Scenario keyword can be:
    • :default 133221
    • :H_mode a prototypical H_mode
    • :L_mode a prototypical L_mode
    • a user defined string pointing to a ODS on file saved in JSON format
    use_scenario_sources keywods says whether core_sources will be taken from scenario or not
    source
    DTT
    EXCITE
    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:EXCITE}})::Tuple{ParametersAllInits,ParametersAllActors}
    GA EXCITE design
    source
    FIRST
    FPP
    HDB5
    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:HDB5}}; tokamak::Union{String,Symbol}=:any, case=missing, database_case=missing)
    For description of cases/variables see https://osf.io/593q6/
    source
    ITER
    FUSE.case_parametersMethod
    case_parameters(
     :ITER,
     init_from::Symbol,
     boundary_from::Symbol=:auto,
     ne_setting::Symbol=:ne_ped,
-    time_dependent::Bool=false)
    ITER
    source
    KDEMO
    MANTA
    FUSE.case_parametersMethod
    case_parameters(:MANTA; flux_matcher::Bool=false)
    MANTA (Modular Adjustable Negative-Triangularity ARC)
    https://arxiv.org/abs/2405.20243
    https://burningplasma.org/resources/ref/WebSeminars/MANTAUSBPOWebinarPresentation.pdf
    source
    SPARC
    STEP
    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:STEP}}; init_from::Symbol=:scalars, pf_from::Symbol=init_from)
    UKAEA STEP design
    source
    baby_MANTA
    
+    time_dependent::Bool=false)

    ITER

    source

    KDEMO

    MANTA

    FUSE.case_parametersMethod
    case_parameters(:MANTA; flux_matcher::Bool=false)

    MANTA (Modular Adjustable Negative-Triangularity ARC)

    https://arxiv.org/abs/2405.20243

    https://burningplasma.org/resources/ref/WebSeminars/MANTAUSBPOWebinarPresentation.pdf

    source

    SPARC

    STEP

    FUSE.case_parametersMethod
    case_parameters(::Type{Val{:STEP}}; init_from::Symbol=:scalars, pf_from::Symbol=init_from)

    UKAEA STEP design

    source

    baby_MANTA

    diff --git a/dev/dd.html b/dev/dd.html index 01b2dc995..c51389cc2 100644 --- a/dev/dd.html +++ b/dev/dd.html @@ -20629,4 +20629,4 @@ │ ├─ time_interval_elapsed [s] │ └─ time_interval_request [s] └─ time [s] - + diff --git a/dev/dd_details.html b/dev/dd_details.html index d542c008a..44af2b8bf 100644 --- a/dev/dd_details.html +++ b/dev/dd_details.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub
    amns_data.a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.code.library[:].name

    Name of software

    • Data Type: STR_0D
    amns_data.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    amns_data.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["amns_data.time"]
    amns_data.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.code.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].extrapolation_type

    Extrapolation strategy when leaving the domain. The first value of the vector describes the behaviour at lower bound, the second describes the at upper bound. Possible values: 0=none, report error; 1=boundary value; 2=linear extrapolation

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    amns_data.coordinate_system[:].coordinate[:].interpolation_type

    Interpolation strategy in this coordinate direction. Integer flag: 0=discrete (no interpolation); 1=linear; ...

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].label

    Description of coordinate (e.g. "Electron temperature")

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].spacing

    Flag for specific coordinate spacing (for optimization purposes). Integer flag: 0=undefined; 1=uniform; ...

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].transformation

    Coordinate transformation applied to coordinate values stored in coord. Integer flag: 0=none; 1=log10; 2=ln

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].units

    Units of coordinate (e.g. eV)

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].value_labels

    String description of discrete coordinate values (if interpolation_type=0). E.g., for spectroscopic lines, the spectroscopic description of the transition.

    • Data Type: STR_1D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.coordinate_system[:].coordinate[:].values

    Coordinate values

    • Units: units given by coordinate_system(:)/coordinate(:)/units
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    amns_data.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    amns_data.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    amns_data.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    amns_data.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    amns_data.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    amns_data.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    amns_data.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    amns_data.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    amns_data.process[:].charge_state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    amns_data.process[:].charge_state[:].table_0d

    0D table describing the process data

    • Units: units given by process(:)/results_units
    • Data Type: FLT_0D
    amns_data.process[:].charge_state[:].table_1d

    1D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_1D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_2d

    2D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_2D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_3d

    3D table describing the process data

    • Units: units given by process(:)/results_units
    • Data Type: FLT_3D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_4d

    4D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_4D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_5d

    5D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_5D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_6d

    6D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_6D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].charge_state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].citation

    Reference to publication(s)

    • Data Type: STR_0D
    amns_data.process[:].coordinate_index

    Index in tables_coord, specifying what coordinate systems to use for this process (valid for all tables)

    • Data Type: INT_0D
    amns_data.process[:].label

    String identifying the process (e.g. EI, RC, ...)

    • Data Type: STR_0D
    amns_data.process[:].products[:].charge

    Charge number of the participant

    • Data Type: FLT_0D
    amns_data.process[:].products[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    amns_data.process[:].products[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].label

    String identifying reaction participant (e.g. "D", "e", "W", "CD4", "photon", "n")

    • Data Type: STR_0D
    amns_data.process[:].products[:].mass

    Mass of the participant

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].metastable

    An array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    amns_data.process[:].products[:].metastable_label

    Label identifying in text form the metastable

    • Data Type: STR_0D
    amns_data.process[:].products[:].multiplicity

    Multiplicity in the reaction

    • Data Type: FLT_0D
    amns_data.process[:].products[:].relative_charge

    This is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundle

    • Data Type: INT_0D
    amns_data.process[:].products[:].role.description

    Verbose description

    • Data Type: STR_0D
    amns_data.process[:].products[:].role.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.process[:].products[:].role.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.process[:].provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].charge

    Charge number of the participant

    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].label

    String identifying reaction participant (e.g. "D", "e", "W", "CD4", "photon", "n")

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].mass

    Mass of the participant

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].metastable

    An array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    amns_data.process[:].reactants[:].metastable_label

    Label identifying in text form the metastable

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].multiplicity

    Multiplicity in the reaction

    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].relative_charge

    This is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundle

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].role.description

    Verbose description

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].role.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].role.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.process[:].result_label

    Description of the process result (rate, cross section, sputtering yield, ...)

    • Data Type: STR_0D
    amns_data.process[:].result_transformation

    Transformation of the process result. Integer flag: 0=no transformation; 1=10^; 2=exp()

    • Data Type: INT_0D
    amns_data.process[:].result_units

    Units of the process result

    • Data Type: STR_0D
    amns_data.process[:].source

    Filename or subroutine name used to provide this data

    • Data Type: STR_0D
    amns_data.process[:].table_dimension

    Table dimensionality of the process (1 to 6), valid for all charge states. Indicates which of the tables is filled (below the charge_state node)

    • Data Type: INT_0D
    amns_data.release[:].data_entry[:].description

    Description of this data entry

    • Data Type: STR_0D
    amns_data.release[:].data_entry[:].run

    Which run number is the active run number for this version

    • Data Type: INT_0D
    amns_data.release[:].data_entry[:].shot

    Shot number = Mass*1000+Nuclear_charge

    • Data Type: INT_0D
    amns_data.release[:].date

    Date of this release

    • Data Type: STR_0D
    amns_data.release[:].description

    Description of this release

    • Data Type: STR_0D
    amns_data.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    amns_data.z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    b_field_non_axisymmetric.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].name

    Name of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["b_field_non_axisymmetric.time"]
    b_field_non_axisymmetric.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.configuration

    In case of a constant (single time slice) b_field description, name of the corresponding scenario/configuration

    • Data Type: STR_0D
    b_field_non_axisymmetric.control_surface_names

    List of control surface names, refers to the ../timeslice/controlsurface index

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal

    Normal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal_fourier

    Fourier coefficients of the normal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_r

    R component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_tor

    Toroidal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_z

    Z component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor

    Toroidal mode number

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].phi

    Toroidal angle array, on which the Fourier decomposition is carried out

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_r

    R component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_tor

    Toroidal component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_z

    Z component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r"]
    b_field_non_axisymmetric.time_slice[:].field_map.ripple_amplitude

    Value of (bfieldmax-bfieldmin)/(bfieldmax+bfieldmin), where bfieldmax resp. bfieldmin) is the maximum (resp. minimum) of the magnetic field amplitude over a 2pi rotation in toroidal angle phi at a given R, Z position.

    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    balance_of_plant.Q_plant

    Electricity gain of the plant (ratio of net electric / plant electricity during operation)

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_net

    Net electric power

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.system[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_electric_plant_operation.system[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_electric_plant_operation.system[:].power

    Electrical power used to operate the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].power

    Electrical power used to operate the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.total_power

    Total

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.generator_conversion_efficiency

    Conversion efficiency of thermal to electric power of the steam cycle

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.breeder

    The heat flow towards the breeder.

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.divertor

    The heat flow towards the divertor

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.wall

    The heat flow towards the wall.

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.power_cycle_type

    Type of primary power cycle, :brayton = gas, :rankine = steam

    • Data Type: STR_0D
    balance_of_plant.power_plant.power_electric_generated

    The net electric power produced by the thermal plant, equal tot the power produced by turbines LESS the power consumed by pumps and compressors

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_plant.system[:].component[:].name

    Name of the component

    • Data Type: STR_0D
    balance_of_plant.power_plant.system[:].component[:].port[:].massflow

    Mass Flow Rate of the fluid

    • Units: kg/s
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].mechanicalPower

    Shaft power associated with the component, (+) = into the system, (-) = out of the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].name

    Name of the port

    • Data Type: STR_0D
    balance_of_plant.power_plant.system[:].component[:].port[:].pressure

    Fluid pressure

    • Units: Bar
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].temperature

    Fluid Temperature

    • Units: C
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].thermalPower

    Heattransfer rate of the component, (+) = into the system, (-) = out of the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_plant.system[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_plant.total_heat_rejected

    The total heat flow being rejected from the thermal plant

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.total_heat_supplied

    The total heat flow being supplied to the thermal Plant (Fusion thermal power).

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.thermal_efficiency_cycle

    The fractional thermal effiency of the power cycle. Calculated as 1-Qout/Qin

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.thermal_efficiency_plant

    The fractional thermal effiency of the entire BOP thermal plant, inlcudes all of the individual cycles. Calculated as 1-Qout/Qin

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    barometry.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.code.library[:].name

    Name of software

    • Data Type: STR_0D
    barometry.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    barometry.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["barometry.time"]
    barometry.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.code.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.gauge[:].calibration_coefficient

    Coefficient used for converting raw signal into absolute pressure

    • Units: Pa
    • Data Type: FLT_0D
    barometry.gauge[:].name

    Name of the gauge

    • Data Type: STR_0D
    barometry.gauge[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    barometry.gauge[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    barometry.gauge[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    barometry.gauge[:].pressure.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["barometry.gauge[:].pressure.time"]
    barometry.gauge[:].pressure.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    barometry.gauge[:].type.description

    Verbose description

    • Data Type: STR_0D
    barometry.gauge[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    barometry.gauge[:].type.name

    Short string identifier

    • Data Type: STR_0D
    barometry.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    barometry.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    barometry.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    barometry.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    barometry.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    barometry.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    barometry.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    barometry.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    barometry.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    barometry.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    barometry.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    barometry.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    barometry.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    barometry.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    barometry.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    blanket.module[:].layer[:].material

    Material of the layer

    • Data Type: STR_0D
    blanket.module[:].layer[:].midplane_thickness

    Thickness of layer evaluated at the midplane

    • Units: m
    • Data Type: FLT_0D
    blanket.module[:].layer[:].name

    Name of the blanket layer

    • Data Type: STR_0D
    blanket.module[:].name

    Name of the blanket module

    • Data Type: STR_0D
    blanket.module[:].time_slice[:].peak_escape_flux

    Maximum neutron flux escaping from the back of the blanket module

    • Units: W/m^2
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].peak_wall_flux

    Maximum neutron flux at the first wall

    • Units: W/m^2
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_incident_neutrons

    Total incident neutron power on the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_incident_radiated

    Total incident radiative power on the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_extracted

    Total thermal power that is extracted from the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_neutrons

    Total neutron power (deposited + generated) in the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_radiated

    Total radiated power (incident - reflected) in the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].tritium_breeding_ratio

    Number of tritium atoms for each incident neutron (TBR)

    • Data Type: FLT_0D
    blanket.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    blanket.tritium_breeding_ratio

    Number of tritium atoms created for each fusion neutron (TBR)

    • Data Type: FLT_1D
    • Coordinates: ["blanket.time"]
    bolometer.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    bolometer.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].aperture[:].outline.x1"]
    bolometer.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    bolometer.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].detector.outline.x1"]
    bolometer.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    bolometer.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    bolometer.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    bolometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    bolometer.channel[:].power.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].power.time"]
    bolometer.channel[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    bolometer.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["bolometer.channel[:].validity_timed.time"]
    bolometer.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    bolometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    bolometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.grid.volume_element

    Volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["bolometer.grid.dim1", "bolometer.grid.dim2"]
    bolometer.grid_type.description

    Verbose description

    • Data Type: STR_0D
    bolometer.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    bolometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    bolometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    bolometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    bolometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    bolometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    bolometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    bolometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    bolometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    bolometer.power_density.data

    Data

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["bolometer.grid.dim1", "bolometer.grid.dim2", "bolometer.power_density.time"]
    bolometer.power_density.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.power_radiated_inside_lcfs

    Radiated power from the plasma inside the Last Closed Flux Surface, reconstructed from bolometry data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.power_radiated_total

    Total radiated power reconstructed from bolometry data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.power_radiated_validity

    Validity flag related to the radiated power reconstructions

    • Data Type: INT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].filter.detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].filter.wavelengths"]
    bremsstrahlung_visible.channel[:].filter.wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].filter.wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].filter.wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].intensity.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].intensity.time"]
    bremsstrahlung_visible.channel[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    bremsstrahlung_visible.channel[:].radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].radiance_spectral.time"]
    bremsstrahlung_visible.channel[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].zeff_line_average.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].zeff_line_average.time"]
    bremsstrahlung_visible.channel[:].zeff_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].zeff_line_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    bremsstrahlung_visible.channel[:].zeff_line_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].zeff_line_average.time"]
    bremsstrahlung_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["bremsstrahlung_visible.time"]
    bremsstrahlung_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    bremsstrahlung_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.divertors.lower.installed

    1 if a lower divertor is installed

    • Data Type: INT_0D
    build.divertors.upper.installed

    1 if a upper divertor is installed

    • Data Type: INT_0D
    build.flux_swing.flattop

    Total flux required for the plasma flattop

    • Units: Wb
    • Data Type: FLT_0D
    build.flux_swing.pf

    Contribution of vertical field from PF coils to flux swing

    • Units: Wb
    • Data Type: FLT_0D
    build.flux_swing.rampup

    Total flux required for the plasma rampup

    • Units: Wb
    • Data Type: FLT_0D
    build.layer[:].area

    Cross sectional area of the layer

    • Units: m^2
    • Data Type: FLT_0D
    build.layer[:].end_radius

    End radius of the layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].identifier

    Integer to identify the same layer on the high-field-side and low-field-side

    • Data Type: INT_0D
    build.layer[:].material

    Material of the layer

    • Data Type: STR_0D
    build.layer[:].name

    Name of the layer

    • Data Type: STR_0D
    build.layer[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.layer[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.layer[:].outline.r"]
    build.layer[:].shape

    Integer to identify the physical shape of the layer

    • Data Type: INT_0D
    build.layer[:].shape_parameters

    List of the shape specific parameters for given shape type

    • Data Type: FLT_1D
    build.layer[:].side

    Integer set to -1 if layer is on the low-field-side and 1 if layer is on the high-field-side. 0 for plasma. 2 for inner (eg. OH) and 3 for outer (eg. cryostat)

    • Data Type: INT_0D
    build.layer[:].start_radius

    Start radius of the layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].thickness

    Radial thickness of layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].type

    Layer type code

    1. vacuum (use this to set mimimum radius for OH)
    2. OH
    3. TF
    4. BL
    5. Shielding
    6. Wall

    -1) Vacuum vessel * Data Type: INT_0D

    build.layer[:].volume

    Volume of the layer

    • Units: m^3
    • Data Type: FLT_0D
    build.layer[:].volume_no_structures

    Volume of the layer without structures

    • Units: m^3
    • Data Type: FLT_0D
    build.oh.critical_b_field

    Critical magnetic field density to quench superconducting OH

    • Units: T
    • Data Type: FLT_0D
    build.oh.critical_j

    Critical current density to quench superconducting OH

    • Units: A/m^2
    • Data Type: FLT_0D
    build.oh.flattop_duration

    Estimated duration of the flattop

    • Units: s
    • Data Type: FLT_0D
    build.oh.max_b_field

    Maximum magnetic field in the OH solenoid, as required to satisfy rampup and flattop flux consumption

    • Units: T
    • Data Type: FLT_0D
    build.oh.max_j

    Maximum current density in the OH solenoid, as required to satisfy rampup and flattop flux consumption

    • Units: A/m^2
    • Data Type: FLT_0D
    build.oh.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the OH coils

    • Data Type: FLT_0D
    build.oh.technology.fraction_steel

    Fraction of stainless steel in the OH coils cross-sectional areas

    • Data Type: FLT_0D
    build.oh.technology.fraction_void

    Fraction of void in the OH coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.oh.technology.material

    Material of the OH coils

    • Data Type: STR_0D
    build.oh.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in OH coils

    • Data Type: FLT_0D
    build.oh.technology.temperature

    OH coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.oh.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the OH coils

    • Data Type: FLT_0D
    build.pf_active.rail[:].coils_cleareance

    Clereance that coils have from other structures

    • Units: m
    • Data Type: FLT_0D
    build.pf_active.rail[:].coils_number

    Number of coils on the rail

    • Data Type: INT_0D
    build.pf_active.rail[:].name

    Name of the coil rail

    • Data Type: STR_0D
    build.pf_active.rail[:].outline.distance

    Distance along the rail skipping gaps

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.pf_active.rail[:].outline.r"]
    build.pf_active.rail[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.pf_active.rail[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.pf_active.rail[:].outline.r"]
    build.pf_active.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the PF coils

    • Data Type: FLT_0D
    build.pf_active.technology.fraction_steel

    Fraction of stainless steel in the PF coils cross-sectional areas

    • Data Type: FLT_0D
    build.pf_active.technology.fraction_void

    Fraction of void in the PF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.pf_active.technology.material

    Material of the PF coils

    • Data Type: STR_0D
    build.pf_active.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in the PF coils

    • Data Type: FLT_0D
    build.pf_active.technology.temperature

    PF coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.pf_active.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the PF coils

    • Data Type: FLT_0D
    build.structure[:].area

    Cross sectional area of the structure

    • Units: m^2
    • Data Type: FLT_0D
    build.structure[:].identifier

    String to identify structure

    • Data Type: STR_0D
    build.structure[:].material

    Material of the structure

    • Data Type: STR_0D
    build.structure[:].name

    Name of the structure

    • Data Type: STR_0D
    build.structure[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.structure[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.structure[:].outline.r"]
    build.structure[:].toroidal_angles

    Toroidal position(s) of the structure

    • Units: rad
    • Data Type: FLT_1D
    build.structure[:].toroidal_extent

    Toroidal extent of the structure

    • Units: rad
    • Data Type: FLT_0D
    build.structure[:].type

    Structure type code

    • Data Type: INT_0D
    build.structure[:].volume

    Volume of the structure

    • Units: m^3
    • Data Type: FLT_0D
    build.tf.coils_n

    Number of TF coils around the torus

    • Data Type: INT_0D
    build.tf.critical_b_field

    Critical magnetic field to quench superconducting TF

    • Units: T
    • Data Type: FLT_0D
    build.tf.critical_j

    Critical current density to quench superconducting TF

    • Units: A/m^2
    • Data Type: FLT_0D
    build.tf.max_b_field

    Maximum magnetic field evaluated at the TF high-field side

    • Units: T
    • Data Type: FLT_0D
    build.tf.max_j

    Maximum current density in the TF solenoid

    • Units: A/m^2
    • Data Type: FLT_0D
    build.tf.ripple

    Fraction of toroidal field ripple evaluated at the outermost radius of the plasma chamber

    • Data Type: FLT_0D
    build.tf.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the TF coils

    • Data Type: FLT_0D
    build.tf.technology.fraction_steel

    Fraction of stainless steel in the TF coils cross-sectional areas

    • Data Type: FLT_0D
    build.tf.technology.fraction_void

    Fraction of void in the TF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.tf.technology.material

    Material of the TF coils

    • Data Type: STR_0D
    build.tf.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in the TF coils

    • Data Type: FLT_0D
    build.tf.technology.temperature

    TF coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.tf.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the TF coils

    • Data Type: FLT_0D
    build.tf.wedge_thickness

    Thickness of the TF coils wedge evaluated

    • Units: m
    • Data Type: FLT_0D
    build.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.code.library[:].name

    Name of software

    • Data Type: STR_0D
    calorimetry.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    calorimetry.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.time"]
    calorimetry.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.code.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].identifier

    ID of the loop

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].mass_flow.data

    Data

    • Units: kg.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].mass_flow.time"]
    calorimetry.cooling_loop[:].mass_flow.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].mass_flow.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].mass_flow.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].mass_flow.time"]
    calorimetry.cooling_loop[:].name

    Name of the loop

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].temperature_in.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_in.time"]
    calorimetry.cooling_loop[:].temperature_in.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].temperature_in.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].temperature_in.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_in.time"]
    calorimetry.cooling_loop[:].temperature_out.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_out.time"]
    calorimetry.cooling_loop[:].temperature_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].temperature_out.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].temperature_out.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_out.time"]
    calorimetry.group[:].component[:].energy_cumulated.data

    Data

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].energy_cumulated.time"]
    calorimetry.group[:].component[:].energy_cumulated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].energy_cumulated.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].energy_cumulated.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].energy_cumulated.time"]
    calorimetry.group[:].component[:].energy_total.data

    Data

    • Units: J
    • Data Type: FLT_0D
    calorimetry.group[:].component[:].energy_total.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].identifier

    ID of the component

    • Data Type: STR_0D
    calorimetry.group[:].component[:].mass_flow.data

    Data

    • Units: kg.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].mass_flow.time"]
    calorimetry.group[:].component[:].mass_flow.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].mass_flow.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].mass_flow.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].mass_flow.time"]
    calorimetry.group[:].component[:].name

    Name of the component

    • Data Type: STR_0D
    calorimetry.group[:].component[:].power.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].power.time"]
    calorimetry.group[:].component[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].power.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].power.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].power.time"]
    calorimetry.group[:].component[:].temperature_in.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_in.time"]
    calorimetry.group[:].component[:].temperature_in.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].temperature_in.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].temperature_in.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_in.time"]
    calorimetry.group[:].component[:].temperature_out.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_out.time"]
    calorimetry.group[:].component[:].temperature_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].temperature_out.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].temperature_out.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_out.time"]
    calorimetry.group[:].component[:].transit_time.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].transit_time.time"]
    calorimetry.group[:].component[:].transit_time.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].transit_time.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].transit_time.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].transit_time.time"]
    calorimetry.group[:].identifier

    ID of the group

    • Data Type: STR_0D
    calorimetry.group[:].name

    Name of the group

    • Data Type: STR_0D
    calorimetry.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    calorimetry.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    calorimetry.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    calorimetry.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    calorimetry.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    calorimetry.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    calorimetry.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    calorimetry.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    calorimetry.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    calorimetry.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.calibration.luminance_to_temperature

    Luminance to temperature conversion table

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...2"]
    camera_ir.calibration.optical_temperature

    Temperature of the optical components (digital levels)

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_barrel

    Transmission of the optical barrel

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_mirror

    Transmission of the mirror

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_window

    Transmission of the window

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_ir.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_ir.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_ir.time"]
    camera_ir.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.fibre_bundle.fibre_positions.x1"]
    camera_ir.fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_ir.fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.fibre_bundle.geometry.outline.x1"]
    camera_ir.fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.frame[:].surface_temperature

    Surface temperature image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis). The size of this matrix is assumed to be constant over time

    • Units: K
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_ir.frame_analysis[:].distance_separatrix_midplane

    Distance between the measurement position and the separatrix, mapped along flux surfaces to the outboard midplane, in the major radius direction. Positive value means the measurement is outside of the separatrix.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.frame_analysis[:].power_flux_parallel

    Parallel heat flux received by the element monitored by the camera, along the distanceseparatrixmidplane coordinate

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.frame_analysis[:].distance_separatrix_midplane"]
    camera_ir.frame_analysis[:].sol_heat_decay_length

    Heat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031

    • Units: m
    • Data Type: FLT_0D
    camera_ir.frame_analysis[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_ir.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_ir.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_ir.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_ir.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_ir.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_ir.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_ir.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_ir.midplane.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.midplane.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.name

    Name of the camera

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_ir.optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].geometry.outline.x1"]
    camera_ir.optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].aperture[:].outline.x1"]
    camera_visible.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].columns_n

    Number of pixel columns in the horizontal direction

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].counts_to_radiance

    Counts to radiance factor, for each pixel of the detector. Includes both the transmission losses in the relay optics and the quantum efficiency of the camera itself, integrated over the wavelength range

    • Units: photons.m^-2.s^-1.sr^-1.counts^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].frame[:].image_raw

    Raw image (unprocessed) (digital levels). First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].frame[:].radiance

    Radiance image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Units: photons.m^-2.s^-1.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3

    Third dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.data

    Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector pixel). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi (third dimension of this array). The first two dimension correspond to the detector pixels : first dimension : line index (horizontal axis); second dimension: column index (vertical axis).

    • Units: m^-2
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.phi

    Toroidal angle (oriented counter-clockwise when viewing from above) of interpolation knots

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r

    Major radius of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.z

    Height of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.voxel_map

    Voxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.

    • Data Type: INT_3D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1", "camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2", "camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3"]
    camera_visible.channel[:].detector[:].geometry_matrix.voxels_n

    Number of voxels defined in the voxel_map.

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.pixel_indices

    List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data", "1...2"]
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.pixel_indices

    List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data", "1...2"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data"]
    camera_visible.channel[:].detector[:].lines_n

    Number of pixel lines in the vertical direction

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].noise

    Detector noise (e.g. read-out noise) (rms counts per second exposure time)

    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].pixel_to_alpha

    Alpha angle of each pixel in the horizontal axis

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].pixel_to_beta

    Beta angle of each pixel in the vertical axis

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].wavelength_lower

    Lower bound of the detector wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].wavelength_upper

    Upper bound of the detector wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].fibre_bundle.fibre_positions.x1"]
    camera_visible.channel[:].fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].fibre_bundle.geometry.outline.x1"]
    camera_visible.channel[:].fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].geometry.outline.x1"]
    camera_visible.channel[:].optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].viewing_angle_alpha_bounds

    Minimum and maximum values of alpha angle of the field of view, where alpha is the agle between the axis X3 and projection of the chord of view on the plane X1X3 counted clockwise from the top view of X2 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_visible.channel[:].viewing_angle_beta_bounds

    Minimum and maximum values of beta angle of the field of view, where beta is the angle between the axis X3 and projection of the chord of view on the plane X2X3 counted clockwise from the top view of X1 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.time"]
    camera_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_visible.name

    Name of the camera

    • Data Type: STR_0D
    camera_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_x_rays.aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.aperture.outline.x1"]
    camera_x_rays.aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.camera_dimensions

    Total camera dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.camera.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.identifier

    ID of the camera

    • Data Type: STR_0D
    camera_x_rays.camera.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_dimensions

    Pixel dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.pixel_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixels_n

    Number of pixels in each direction (x1, x2)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_x_rays.time"]
    camera_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.detector_humidity.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.detector_humidity.time"]
    camera_x_rays.detector_humidity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.detector_temperature.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.detector_temperature.time"]
    camera_x_rays.detector_temperature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.energy_configuration_name

    Name of the chosen energy configuration (energy detection threshold)

    • Data Type: STR_0D
    camera_x_rays.energy_threshold_lower

    Lower energy detection threshold on each pixel of the detector (photons are counted only if their energy is above this value)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.identifier

    ID of the filter

    • Data Type: STR_0D
    camera_x_rays.filter_window.material.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.material.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.filter_window.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.filter_window.outline.x1"]
    camera_x_rays.filter_window.photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.filter_window.wavelengths"]
    camera_x_rays.filter_window.radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_x_rays.filter_window.thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.filter_window.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.frame[:].counts_n

    Number of counts detected on each pixel during one exposure time. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.name

    Name of the camera

    • Data Type: STR_0D
    camera_x_rays.photon_energy

    List of values of the photon energy (coordinate for quantum_effiency)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.pixel_status

    Status of each pixel : +1 for valid pixels, -1 for inactive pixels, -2 for mis-calibrated pixels.

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.quantum_efficiency

    Quantum efficiency of the detector, i.e. conversion factor multiplying the number of counts to obtain the number of photons impacting the detector, tabulated as a function of the photon energy, for each pixel of the detector. If all pixels have the same quantum efficiency, just set the size of the first and second dimensions to 1

    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "camera_x_rays.photon_energy"]
    camera_x_rays.readout_time

    Time used to read out each frame on the detector

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    charge_exchange.aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    charge_exchange.aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.aperture.outline.x1"]
    charge_exchange.aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.a

    Mass of atom of the diagnostic neutral beam particle

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.doppler_shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].bes.doppler_shift.time"]
    charge_exchange.channel[:].bes.doppler_shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.label

    String identifying the diagnostic neutral beam particle

    • Data Type: STR_0D
    charge_exchange.channel[:].bes.lorentz_shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].bes.lorentz_shift.time"]
    charge_exchange.channel[:].bes.lorentz_shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.radiances.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].bes.radiances.time"]
    charge_exchange.channel[:].bes.radiances.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.transition_wavelength

    Unshifted wavelength of the BES transition

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.z_ion

    Ion charge of the diagnostic neutral beam particle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.z_n

    Nuclear charge of the diagnostic neutral beam particle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].a

    Mass of atom of the ion

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion[:].label

    String identifying the ion (e.g. H+, D+, T+, He+2, C+6, ...)

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].n_i_over_n_e.time"]
    charge_exchange.channel[:].ion[:].n_i_over_n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].t_i.time"]
    charge_exchange.channel[:].ion[:].t_i.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].t_i_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].t_i_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].t_i_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_pol.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].velocity_pol.time"]
    charge_exchange.channel[:].ion[:].velocity_pol.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].velocity_pol_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_pol_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].velocity_pol_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_tor.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].velocity_tor.time"]
    charge_exchange.channel[:].ion[:].velocity_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].velocity_tor_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_tor_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].velocity_tor_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].z_ion

    Ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].a

    Mass of atom of the fast ion

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].label

    String identifying the fast ion (e.g. H+, D+, T+, He+2, C+6, ...)

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].radiance.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion_fast[:].radiance.time"]
    charge_exchange.channel[:].ion_fast[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].transition_wavelength

    Unshifted wavelength of the fast ion charge exchange transition

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].z_ion

    Fast ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].z_n

    Nuclear charge of the fast ion

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].momentum_tor.data

    Data

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].momentum_tor.time"]
    charge_exchange.channel[:].momentum_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].momentum_tor_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].momentum_tor_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].momentum_tor_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    charge_exchange.channel[:].position.phi.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.phi.time"]
    charge_exchange.channel[:].position.phi.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].position.r.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.r.time"]
    charge_exchange.channel[:].position.r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].position.z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.z.time"]
    charge_exchange.channel[:].position.z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].grating

    Number of grating lines per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].instrument_function

    Array of Gaussian widths and amplitudes which as a sum make up the instrument fuction. IF(lambda) = sum( instrumentfunction(1,i)/sqrt(2 * pi * instrumentfunction(2,i)^2 ) * exp( -lambda^2/(2 * instrumentfunction(2,i)^2) ) ),whereby sum( instrumentfunction(1,i) ) = 1

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    charge_exchange.channel[:].spectrum[:].intensity_spectrum.data

    Data

    • Units: (photoelectrons).s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].intensity_spectrum.time"]
    charge_exchange.channel[:].spectrum[:].intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.data

    Data

    • Units: (photonelectrons).s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].label

    String identifying the processed spectral line: Spectroscopy notation emitting element (e.g. D I, Be IV, W I, C VI), transition - if known - between round brackets (e.g. (3-2) ) and indication type of charge exchange - if applicable - between square brackets (e.g. [ACX] or [PCX]). Example for beryllium active charge exchange line at 468.5 nm: 'Be IV (8-6) [ACX]'. Example for impact excitation tungsten line coming from the plasma edge: 'W I'

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].wavelength_central

    Unshifted central wavelength of the processed spectral line

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].processed_line[:].width.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].width.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].width.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].wavelengths"]
    charge_exchange.channel[:].spectrum[:].radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].radiance_continuum.data

    Data

    • Units: m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].radiance_continuum.time"]
    charge_exchange.channel[:].spectrum[:].radiance_continuum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].radiance_spectral.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].radiance_spectral.time"]
    charge_exchange.channel[:].spectrum[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].slit_width

    Width of the slit (placed in the object focal plane)

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].t_i_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].t_i_average.time"]
    charge_exchange.channel[:].t_i_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].t_i_average_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].t_i_average_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].t_i_average_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].zeff.time"]
    charge_exchange.channel[:].zeff.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].zeff_line_average.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].zeff_line_average.time"]
    charge_exchange.channel[:].zeff_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].zeff_line_average_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_line_average_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].zeff_line_average_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].zeff_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.code.library[:].name

    Name of software

    • Data Type: STR_0D
    charge_exchange.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    charge_exchange.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["charge_exchange.time"]
    charge_exchange.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.code.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.etendue

    Etendue (geometric extent) of the optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    charge_exchange.etendue_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    charge_exchange.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    charge_exchange.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    charge_exchange.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    charge_exchange.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    charge_exchange.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    charge_exchange.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    charge_exchange.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].name

    Name of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["coils_non_axisymmetric.time"]
    coils_non_axisymmetric.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.code.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].area

    Area of the conductor cross-section, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].height

    Full height of the rectangle in the binormal direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.binormal

    Coordinates along the binormal axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.normal"]
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.normal

    Coordinate along the normal axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].radius_inner

    Inner radius of the annulus, used only if geometry_type/index = 5

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].width

    Full width of the rectangle or square in the normal direction, when geometrytype/index = 3 or 4. Diameter of the circle when geometrytype/index = 2. Outer diameter of the annulus in case geometry_type/index = 5

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.types

    Type of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circle

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].conductor[:].resistance

    conductor resistance

    • Units: Ohm
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].voltage.time"]
    coils_non_axisymmetric.coil[:].conductor[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].current.time"]
    coils_non_axisymmetric.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].identifier

    Alphanumeric identifier of coil

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].turns

    Number of total turns in the coil. May be a fraction when describing the coil connections.

    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].voltage.time"]
    coils_non_axisymmetric.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    coils_non_axisymmetric.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.code.library[:].name

    Name of software

    • Data Type: STR_0D
    controllers.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    controllers.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["controllers.time"]
    controllers.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.code.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.controllability_metrics[:].data

    Array of scalar metrics in time

    • Data Type: FLT_1D
    controllers.controllability_metrics[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    controllers.controllability_metrics[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    controllers.controllability_metrics[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    controllers.controllability_metrics[:].time

    Controlability metric time

    • Units: s
    • Data Type: FLT_1D
    controllers.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    controllers.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    controllers.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    controllers.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    controllers.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    controllers.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    controllers.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    controllers.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    controllers.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    controllers.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    controllers.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    controllers.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    controllers.linear_controller[:].controller_class

    One of a known class of controllers

    • Data Type: STR_0D
    controllers.linear_controller[:].description

    Description of this controller

    • Data Type: STR_0D
    controllers.linear_controller[:].input_names

    Names of the input signals, following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].inputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.linear_controller[:].inputs.time"]
    controllers.linear_controller[:].inputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].name

    Name of this controller

    • Data Type: STR_0D
    controllers.linear_controller[:].output_names

    Names of the output signals following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].outputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.linear_controller[:].outputs.time"]
    controllers.linear_controller[:].outputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.d.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.d.time"]
    controllers.linear_controller[:].pid.d.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.i.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.i.time"]
    controllers.linear_controller[:].pid.i.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.p.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.p.time"]
    controllers.linear_controller[:].pid.p.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.tau.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["controllers.linear_controller[:].pid.tau.time"]
    controllers.linear_controller[:].pid.tau.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.a.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].statespace.a.time"]
    controllers.linear_controller[:].statespace.a.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.b.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].statespace.b.time"]
    controllers.linear_controller[:].statespace.b.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.c.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].output_names", "controllers.linear_controller[:].statespace.c.time"]
    controllers.linear_controller[:].statespace.c.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.d.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].output_names", "controllers.linear_controller[:].statespace.d.time"]
    controllers.linear_controller[:].statespace.d.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.deltat.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["controllers.linear_controller[:].statespace.deltat.time"]
    controllers.linear_controller[:].statespace.deltat.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.state_names

    Names of the states

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].controller_class

    One of a known class of controllers

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].description

    Description of this controller

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].function

    Method to be defined

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].input_names

    Names of the input signals, following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].inputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.nonlinear_controller[:].inputs.time"]
    controllers.nonlinear_controller[:].inputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].name

    Name of this controller

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].output_names

    Output signal names following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].outputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.nonlinear_controller[:].outputs.time"]
    controllers.nonlinear_controller[:].outputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_instant_changes.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_instant_changes.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.time"]
    core_instant_changes.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_instant_changes.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_instant_changes.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_instant_changes.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_instant_changes.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_instant_changes.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_instant_changes.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.time"]
    core_instant_changes.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_profiles.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_profiles.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_profiles.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.covariance.data

    Covariance matrix

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.covariance.rows_uri", "core_profiles.covariance.rows_uri"]
    core_profiles.covariance.description

    Description of this covariance matrix

    • Data Type: STR_0D
    core_profiles.covariance.rows_uri

    List of URIs corresponding to the rows (1st dimension) of the covariance matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector it is sufficient to give a single URI where this vector is denoted using the (:) implicit notation, e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_profiles.global_quantities.beta_pol

    Poloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.beta_tor

    Toroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.beta_tor_norm

    Normalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA]

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_bootstrap

    Bootstrap current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_non_inductive

    Total non-inductive current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_ohmic

    Ohmic current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ejima

    Ejima coefficient : resistive psi losses divided by (mu0RIp). See S. Ejima et al, Nuclear Fusion, Vol.22, No.10 (1982), 1313

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.energy_diamagnetic

    Plasma energy content = 3/2 * integral over the plasma volume of the total perpendicular pressure

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion[:].n_i_volume_average

    Volume averaged density of this ion species (averaged over the plasma volume up to the LCFS)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion[:].t_i_volume_average

    Volume averaged temperature of this ion species (averaged over the plasma volume up to the LCFS)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion_time_slice

    Time slice of the profiles1d array used to define the ion composition of the globalquantities/ion array.

    • Units: s
    • Data Type: FLT_0D
    core_profiles.global_quantities.ip

    Total plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.li_3

    Internal inductance. The li3 definition is used, i.e. li3 = 2/R0/mu0^2/Ip^2 * int(Bp^2 dV).

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.n_e_volume_average

    Volume averaged electron density (average over the plasma volume up to the LCFS)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.polarized_fuel_fraction

    N/A

    • Data Type: FLT_0D
    core_profiles.global_quantities.resistive_psi_losses

    Resistive part of the poloidal flux losses, defined as the volume-averaged scalar product of the electric field and the ohmic current density, normalized by the plasma current and integrated in time from the beginning of the plasma discharge: int ( (int(Efieldtor.johmtor) dV) / Ip ) dt)

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_e_peaking

    Electron temperature peaking factor, defined as the Te value at the magnetic axis divided by the volume averaged Te (average over the plasma volume up to the LCFS)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_e_volume_average

    Volume averaged electron temperature (average over the plasma volume up to the LCFS)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_i_average_peaking

    Ion temperature (averaged over ion species and states) peaking factor, defined as the Ti value at the magnetic axis divided by the volume averaged Ti (average over the plasma volume up to the LCFS)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.v_loop

    LCFS loop voltage (positive value drives positive ohmic current that flows anti-clockwise when viewed from above)

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.z_eff_resistive

    Volume average plasma effective charge, estimated from the flux consumption in the ohmic phase

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_profiles.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_profiles.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_profiles.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_profiles.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_profiles.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_profiles.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].grid.psi_norm

    Normalized poloidal magnetic flux

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure

    Total pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].ion_index

    Index of the corresponding ion species in the ../../../profiles_1d/ion array

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].t_i_average

    Ion temperature (averaged on states and ion species)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].zeff

    Effective charge

    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.statistics[:].quantity_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].quantity_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].quantity_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics value

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path

    For Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3)

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].value

    Value of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.statistics[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.statistics[:].time_width

    Width of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    core_profiles.statistics[:].uq_input_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].uq_input_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].uq_input_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    core_profiles.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_sources.time"]
    core_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_sources.source[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.source[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.source[:].code.name

    Name of software used

    • Data Type: STR_0D
    core_sources.source[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["core_sources.source[:].code.output_flag.time"]
    core_sources.source[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.source[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.source[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.source[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.source[:].global_quantities[:].current_parallel

    Parallel current driven

    • Units: A
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].electrons.particles

    Electron particle source

    • Units: s^-1
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].electrons.power

    Power coupled to electrons

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].power

    Total power coupled to the plasma

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].torque_tor

    Toroidal torque

    • Units: kg.m^2.s^-2
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].total_ion_particles

    Total ion particle source (summed over ion species)

    • Units: (ions).s^-1
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].total_ion_power

    Total power coupled to ion species (summed over ion species)

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity due to this source

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_parallel

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy

    Source term for the electron energy equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles

    Source term for electron density equation

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_inside

    Electron source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.power_inside

    Power coupled to electrons inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].grid.psi_norm

    Normalized poloidal magnetic flux

    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.source[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].energy

    Source term for the ion energy transport equation.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].fast_particles_energy

    Incoming energy of the fast ion particles (eg. fusion 3.5MeV alphas or 1MeV nbi)

    • Units: eV
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].momentum.diamagnetic

    Diamagnetic component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.parallel

    Parallel component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.poloidal

    Poloidal component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.radial

    Radial component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal

    Toroidal component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.explicit_part

    Explicit part of the source term

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].particles

    Source term for ion density equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_inside

    Ion source inside the flux surface. Cumulative volume integral of the source term for the ion density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].power_inside

    Power coupled to the ion species inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy

    Source terms for the charge state energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles

    Source term for the charge state density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_inside

    State source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].power_inside

    Power coupled to the state inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].j_parallel

    Parallel current density source, average(J.B) / B0, where B0 = coresources/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].momentum_tor

    Source term for total toroidal momentum equation

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].momentum_tor_j_cross_b_field

    Contribution to the toroidal momentum source term (already included in the momentum_tor node) corresponding to the toroidal torques onto the thermal plasma due to Lorentz force associated with radial currents. These currents appear as return-currents (enforcing quasi-neutrality, div(J)=0) balancing radial currents of non-thermal particles, e.g. radial currents of fast and trapped neutral-beam-ions.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].energy

    Source term for the neutral energy transport equation.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].particles

    Source term for neutral density equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].energy

    Source terms for the state energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].particles

    Source term for the state density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].torque_tor_inside

    Toroidal torque inside the flux surface. Cumulative volume integral of the source term for the total toroidal momentum equation

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy

    Source term for the total (summed over ion species) energy equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_power_inside

    Total power coupled to ion species (summed over ion species) inside the flux surface. Cumulative volume integral of the source term for the total ion energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.time"]
    core_sources.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_transport.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_transport.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_transport.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_transport.time"]
    core_transport.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_transport.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_transport.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_transport.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_transport.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_transport.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_transport.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_transport.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_transport.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_transport.model[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.model[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.model[:].code.name

    Name of software used

    • Data Type: STR_0D
    core_transport.model[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["core_transport.model[:].code.output_flag.time"]
    core_transport.model[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.model[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.model[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.model[:].comment

    Any comment describing the model

    • Data Type: STR_0D
    core_transport.model[:].flux_multiplier

    Multiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2

    • Data Type: FLT_0D
    core_transport.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_transport.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_transport.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].e_field_radial

    Radial component of the electric field (calculated e.g. by a neoclassical model)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_d.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_d.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_d.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_flux.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_flux.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_flux.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_v.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_v.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_v.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].momentum_tor.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].momentum_tor.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].momentum_tor.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].total_ion_energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].total_ion_energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].total_ion_energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.time"]
    core_transport.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    costing.availability

    Availability fraction of the plant

    • Data Type: FLT_0D
    costing.construction_start_year

    Year that plant construction begins

    • Units: year
    • Data Type: INT_0D
    costing.cost_decommissioning.cost

    Cost to decomission the plant

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].cost

    Cost to decommission the system

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].name

    Name of the system to decommission

    • Data Type: STR_0D
    costing.cost_decommissioning.system[:].subsystem[:].cost

    Cost to decommission the subsystem

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].subsystem[:].name

    Name of the subsystem to decommission

    • Data Type: STR_0D
    costing.cost_direct_capital.cost

    Total direct capital

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].cost

    Cost of the system

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].name

    Name of the system

    • Data Type: STR_0D
    costing.cost_direct_capital.system[:].subsystem[:].cost

    Cost of the subsystem

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].subsystem[:].name

    Name of the subsystem

    • Data Type: STR_0D
    costing.cost_lifetime

    Total cost of fusion power plant

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_operations.system[:].name

    Name of the system

    • Data Type: STR_0D
    costing.cost_operations.system[:].subsystem[:].name

    Name of the subsystem

    • Data Type: STR_0D
    costing.cost_operations.system[:].subsystem[:].yearly_cost

    Cost of the subsystem per year

    • Units: $M/year
    • Data Type: FLT_0D
    costing.cost_operations.system[:].yearly_cost

    Cost of system per year

    • Units: $M/year
    • Data Type: FLT_0D
    costing.cost_operations.yearly_cost

    Anual cost to operate the plant

    • Units: $M/year
    • Data Type: FLT_0D
    costing.future.inflation_rate

    Predicted average rate of future inflation

    • Data Type: FLT_0D
    costing.future.learning.hts.learning_rate

    Learning rate for ReBCO technology production

    • Data Type: FLT_0D
    costing.future.learning.hts.production_increase

    Factor by which production of ReBCO multiplies

    • Data Type: FLT_0D
    costing.levelized_CoE

    Levelized cost of electiricity (total cost / total electricy generated)

    • Units: $/kWh
    • Data Type: FLT_0D
    costing.plant_lifetime

    Lifetime of the plant

    • Units: year
    • Data Type: INT_0D
    costing.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.code.library[:].name

    Name of software

    • Data Type: STR_0D
    cryostat.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    cryostat.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["cryostat.time"]
    cryostat.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.code.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    cryostat.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    cryostat.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    cryostat.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    cryostat.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    cryostat.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    cryostat.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    cryostat.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    cryostat.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_description.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    dataset_description.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    dataset_description.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    dataset_description.data_entry.run

    Run number

    • Data Type: INT_0D
    dataset_description.data_entry.user

    Username

    • Data Type: STR_0D
    dataset_description.dd_version

    Version of the physics data dictionary of this dataset

    • Data Type: STR_0D
    dataset_description.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    dataset_description.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    dataset_description.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    dataset_description.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    dataset_description.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    dataset_description.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    dataset_description.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    dataset_description.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_description.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.imas_version

    Version of the IMAS infrastructure used to produce this data entry. Refers to the global IMAS repository which links to versions of every infrastructure tools

    • Data Type: STR_0D
    dataset_description.parent_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    dataset_description.parent_entry.pulse

    Pulse number

    • Data Type: INT_0D
    dataset_description.parent_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    dataset_description.parent_entry.run

    Run number

    • Data Type: INT_0D
    dataset_description.parent_entry.user

    Username

    • Data Type: STR_0D
    dataset_description.pulse_time_begin

    Date and time (UTC) at which the pulse started on the experiment, expressed in a human readable form (ISO 8601) : the format of the string shall be : YYYY-MM-DDTHH:MM:SSZ. Example : 2020-07-24T14:19:00Z

    • Data Type: STR_0D
    dataset_description.pulse_time_begin_epoch.nanoseconds

    Elapsed nanoseconds since the time in seconds indicated above

    • Data Type: INT_0D
    dataset_description.pulse_time_begin_epoch.seconds

    Elapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)

    • Data Type: INT_0D
    dataset_description.pulse_time_end_epoch.nanoseconds

    Elapsed nanoseconds since the time in seconds indicated above

    • Data Type: INT_0D
    dataset_description.pulse_time_end_epoch.seconds

    Elapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)

    • Data Type: INT_0D
    dataset_description.simulation.comment_after

    Comment made at the end of a simulation

    • Data Type: STR_0D
    dataset_description.simulation.comment_before

    Comment made when launching a simulation

    • Data Type: STR_0D
    dataset_description.simulation.time_begin

    Start time

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_begun

    Actual wall-clock time simulation started

    • Units: UTC
    • Data Type: STR_0D
    dataset_description.simulation.time_current

    Current time of the simulation

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_end

    Stop time

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_ended

    Actual wall-clock time simulation finished

    • Units: UTC
    • Data Type: STR_0D
    dataset_description.simulation.time_restart

    Time of the last restart done during the simulation

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_step

    Time interval between main steps, e.g. storage step (if relevant and constant)

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.workflow

    Description of the workflow which has been used to produce this data entry (e.g. copy of the Kepler MOML if using Kepler)

    • Data Type: STR_0D
    dataset_description.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_fair.identifier

    Persistent identifier allowing to cite this data in a public and persistent way, should be provided as HTTP URIs

    • Data Type: STR_0D
    dataset_fair.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    dataset_fair.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    dataset_fair.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    dataset_fair.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    dataset_fair.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    dataset_fair.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    dataset_fair.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    dataset_fair.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_fair.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.is_referenced_by

    List of documents (e.g. publications) or datasets making use of this data entry (e.g. PIDs of other datasets using this data entry as input)

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_fair.is_replaced_by

    Persistent identifier referencing the new version of this data (replacing the present version)

    • Data Type: STR_0D
    dataset_fair.license

    License(s) under which the data is made available (license description or, more convenient, publicly accessible URL pointing to the full license text)

    • Data Type: STR_0D
    dataset_fair.replaces

    Persistent identifier referencing the previous version of this data

    • Data Type: STR_0D
    dataset_fair.rights_holder

    The organisation owning or managing rights over this data

    • Data Type: STR_0D
    dataset_fair.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_fair.valid

    Date range during which the data is or was valid. Expressed as YYYY-MM-DD/YYYY-MM-DD, where the former (resp. latter) date is the data at which the data started (resp. ceased) to be valid. If the data is still valid, the slash should still be present, i.e. indicate the validity start date with YYYY-MM-DD/. If the data ceased being valid but there is no information on the validity start date, indicate /YYYY-MM-DD.

    • Data Type: STR_0D
    disruption.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.code.library[:].name

    Name of software

    • Data Type: STR_0D
    disruption.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    disruption.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["disruption.time"]
    disruption.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.code.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.global_quantities.current_halo_pol

    Poloidal halo current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.current_halo_tor

    Toroidal halo current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_ohm

    Total ohmic cumulated energy (integral of the power over the disruption duration)

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_ohm_halo

    Ohmic cumulated energy (integral of the power over the disruption duration) in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_parallel_halo

    Cumulated parallel energy (integral of the heat flux parallel power over the disruption duration) in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_radiated_electrons_impurities

    Total cumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_radiated_electrons_impurities_halo

    Cumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_ohm

    Total ohmic power

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_ohm_halo

    Ohmic power in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_parallel_halo

    Power of the parallel heat flux in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_radiated_electrons_impurities

    Total power radiated by electrons on impurities

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_radiated_electrons_impurities_halo

    Power radiated by electrons on impurities in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.psi_halo_boundary

    Poloidal flux at halo region boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.halo_currents[:].active_wall_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].active_wall_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].current_halo_pol

    Poloidal halo current crossing through this area

    • Units: A
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].end_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].end_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].start_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].start_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    disruption.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    disruption.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    disruption.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    disruption.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    disruption.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    disruption.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    disruption.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    disruption.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    disruption.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    disruption.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    disruption.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    disruption.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    disruption.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    disruption.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    disruption.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    disruption.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    disruption.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].j_runaways

    Runaways parallel current density = average(j.B) / B0, where B0 = Disruption/VacuumToroidalField/ B0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].power_density_conductive_losses

    Power density of conductive losses to the wall (positive sign for losses)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].power_density_radiative_losses

    Power density of radiative losses (positive sign for losses)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    disruption.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    disruption.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    distribution_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    distribution_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    distribution_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    distribution_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    distribution_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    distribution_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    distribution_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    distribution_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.source[:].ggd[:].discrete

    List of indices of grid spaces (refers to ../grid/space) for which the source is discretely distributed. For example consider a source of 3.5 MeV alpha particles provided on a grid with two coordinates (spaces); rho_tor and energy. To specify that the source is given at energies exactly equal to 3.5 MeV, let discret have length 1 and set discrete(1)=2 since energy is dimension number 2. The source is then proportional to delta( 1 - energy / 3.5MeV ), where delta is the direct delta distribution. Discrete dimensions can only be used when the grid is rectangular.

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: (m.s^-1)^-3.m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["distribution_sources.source[:].ggd[:].particles[:].values", "1...N"]
    distribution_sources.source[:].ggd[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: (m.s^-1)^-3.m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].particles

    Particle source rate

    • Units: s^-1
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].power

    Total power of the source

    • Units: W
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.particles

    Particle losses due to shinethrough

    • Units: s^-1
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.power

    Power losses due to shinethrough

    • Units: W
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.torque_tor

    Toroidal torque losses due to shinethrough

    • Units: N.m
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].torque_tor

    Total toroidal torque of the source

    • Units: N.m
    • Data Type: FLT_0D
    distribution_sources.source[:].gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["distribution_sources.source[:].markers[:].orbit_integrals.expressions", "distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].orbit_integrals.n_tor", "distribution_sources.source[:].markers[:].orbit_integrals.m_pol", "distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions", "distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit"]
    distribution_sources.source[:].markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].coordinate_identifier"]
    distribution_sources.source[:].markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].process[:].nbi_beamlets_group

    Index of the NBI beamlets group considered. Refers to the "unit/beamlets_group" array of the NBI IDS. 0 means sum over all beamlets groups.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].nbi_energy.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].nbi_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].nbi_energy.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].nbi_unit

    Index of the NBI unit considered. Refers to the "unit" array of the NBI IDS. 0 means sum over all NBI units.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].reactant_energy.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].reactant_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].reactant_energy.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].profiles_1d[:].energy

    Source term for the energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distribution_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distribution_sources.source[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].momentum_tor

    Source term for the toroidal momentum equation

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].particles

    Source term for the density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distribution_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distribution_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distribution_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    distributions.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.code.library[:].name

    Name of software

    • Data Type: STR_0D
    distributions.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    distributions.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["distributions.time"]
    distributions.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.code.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values", "1...N"]
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values", "1...N"]
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].temperature

    Reference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].current_tor

    Toroidal current driven by the distribution

    • Units: A
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy

    Total energy in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy_fast

    Total energy of the fast particles in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy_fast_parallel

    Parallel energy of the fast particles in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].particles_fast_n

    Number of fast particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)

    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].particles_n

    Number of particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)

    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].particles

    Particle source rate

    • Units: s^-1
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].power

    Total power of the source

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].torque_tor

    Total toroidal torque of the source

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.particles

    Source rate of thermal particles due to the thermalisation of fast particles

    • Units: s^-1
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.power

    Power input to the thermal particle population due to the thermalisation of fast particles

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.torque

    Torque input to the thermal particle population due to the thermalisation of fast particles

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    distributions.distribution[:].is_delta_f

    If isdeltaf=1, then the distribution represents the deviation from a Maxwellian; isdeltaf=0, then the distribution represents all particles, i.e. the full-f solution

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["distributions.distribution[:].markers[:].orbit_integrals.expressions", "distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].orbit_integrals.n_tor", "distributions.distribution[:].markers[:].orbit_integrals.m_pol", "distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["distributions.distribution[:].markers[:].orbit_integrals_instant.expressions", "distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit"]
    distributions.distribution[:].markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].coordinate_identifier"]
    distributions.distribution[:].markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].process[:].nbi_beamlets_group

    Index of the NBI beamlets group considered. Refers to the "unit/beamlets_group" array of the NBI IDS. 0 means sum over all beamlets groups.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].nbi_energy.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].nbi_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].nbi_energy.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].process[:].nbi_unit

    Index of the NBI unit considered. Refers to the "unit" array of the NBI IDS. 0 means sum over all NBI units.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].reactant_energy.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].reactant_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].reactant_energy.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].process[:].type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].fast_filter.energy

    Energy at which the fast and thermal particle populations were separated, as a function of radius

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].fast_filter.method.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].fast_filter.method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].fast_filter.method.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.energy

    Source rate of energy density within the thermal particle population due to the thermalisation of fast particles

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.momentum_tor

    Source rate of toroidal angular momentum density within the thermal particle population due to the thermalisation of fast particles

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.particles

    Source rate of thermal particle density due to the thermalisation of fast particles

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.rho_tor

    Toroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.theta_geometric

    Geometrical poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.theta_straight

    Straight field line poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].grid.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].grid.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].antenna_name

    Name of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].index_in_antenna

    Index of the wave (starts at 1), separating different waves generated from a single antenna.

    • Data Type: INT_0D
    distributions.distribution[:].wave[:].type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].wave[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    distributions.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    distributions.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    distributions.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    distributions.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    distributions.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    distributions.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    distributions.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    distributions.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    distributions.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    distributions.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    divertors.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.code.library[:].name

    Name of software

    • Data Type: STR_0D
    divertors.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    divertors.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["divertors.time"]
    divertors.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.code.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.divertor[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].current_incident.time"]
    divertors.divertor[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].identifier

    Alphanumeric identifier of divertor

    • Data Type: STR_0D
    divertors.divertor[:].name

    Name of the divertor

    • Data Type: STR_0D
    divertors.divertor[:].particle_flux_recycled_total.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].particle_flux_recycled_total.time"]
    divertors.divertor[:].particle_flux_recycled_total.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_black_body.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_black_body.time"]
    divertors.divertor[:].power_black_body.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_conducted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_conducted.time"]
    divertors.divertor[:].power_conducted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_convected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_convected.time"]
    divertors.divertor[:].power_convected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_currents.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_currents.time"]
    divertors.divertor[:].power_currents.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_incident.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_incident.time"]
    divertors.divertor[:].power_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_neutrals.time"]
    divertors.divertor[:].power_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_radiated.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_radiated.time"]
    divertors.divertor[:].power_radiated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_recombination_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_recombination_neutrals.time"]
    divertors.divertor[:].power_recombination_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_recombination_plasma.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_recombination_plasma.time"]
    divertors.divertor[:].power_recombination_plasma.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_thermal_extracted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_thermal_extracted.time"]
    divertors.divertor[:].power_thermal_extracted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].current_incident.time"]
    divertors.divertor[:].target[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].extension_r

    Target length projected on the major radius axis

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].extension_z

    Target length projected on the height axis

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].flux_expansion.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].flux_expansion.time"]
    divertors.divertor[:].target[:].flux_expansion.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].heat_flux_steady_limit_max

    Maximum steady state heat flux allowed on divertor target surface (engineering design limit)

    • Units: W.m^-2
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].identifier

    Alphanumeric identifier of target

    • Data Type: STR_0D
    divertors.divertor[:].target[:].name

    Name of the target

    • Data Type: STR_0D
    divertors.divertor[:].target[:].power_black_body.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_black_body.time"]
    divertors.divertor[:].target[:].power_black_body.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_conducted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_conducted.time"]
    divertors.divertor[:].target[:].power_conducted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_convected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_convected.time"]
    divertors.divertor[:].target[:].power_convected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_currents.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_currents.time"]
    divertors.divertor[:].target[:].power_currents.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_flux_peak.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_flux_peak.time"]
    divertors.divertor[:].target[:].power_flux_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_incident.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_incident.time"]
    divertors.divertor[:].target[:].power_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_incident_fraction.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_incident_fraction.time"]
    divertors.divertor[:].target[:].power_incident_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_neutrals.time"]
    divertors.divertor[:].target[:].power_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_radiated.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_radiated.time"]
    divertors.divertor[:].target[:].power_radiated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_recombination_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_recombination_neutrals.time"]
    divertors.divertor[:].target[:].power_recombination_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_recombination_plasma.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_recombination_plasma.time"]
    divertors.divertor[:].target[:].power_recombination_plasma.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].t_e_target_sputtering_limit_max

    Maximum plasma temperature allowed on the divertor target to avoid excessive sputtering

    • Units: eV
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].temperature_limit_max

    Maximum surface target temperature allowed to prevent damage (melting, recrystallization, sublimation, etc...)

    • Units: K
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].tile[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].current_incident.time"]
    divertors.divertor[:].target[:].tile[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tile[:].identifier

    Alphanumeric identifier of tile

    • Data Type: STR_0D
    divertors.divertor[:].target[:].tile[:].name

    Name of the tile

    • Data Type: STR_0D
    divertors.divertor[:].target[:].tile[:].shunt_index

    If the tile carries a measurement shunt, index of that shunt (in the magnetics IDS shunt array)

    • Data Type: INT_0D
    divertors.divertor[:].target[:].tile[:].surface_area

    Area of the tile surface facing the plasma

    • Units: m^2
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].tile[:].surface_outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].surface_outline.r"]
    divertors.divertor[:].target[:].tile[:].surface_outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tile[:].surface_outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].surface_outline.r"]
    divertors.divertor[:].target[:].tilt_angle_pol.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tilt_angle_pol.time"]
    divertors.divertor[:].target[:].tilt_angle_pol.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tilt_angle_tor.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tilt_angle_tor.time"]
    divertors.divertor[:].target[:].tilt_angle_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].two_point_model[:].n_e_target

    Electron density at divertor target

    • Units: m^-3
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].sol_heat_decay_length

    Heat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].sol_heat_spreading_length

    Heat flux spreading length in SOL at equatorial mid-plane, this is the S power spreading parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031. Relevant only for attached plasmas.

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].t_e_target

    Electron temperature at divertor target

    • Units: eV
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].wetted_area.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].wetted_area.time"]
    divertors.divertor[:].target[:].wetted_area.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].wetted_area.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].wetted_area.time"]
    divertors.divertor[:].wetted_area.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    divertors.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    divertors.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    divertors.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    divertors.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    divertors.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    divertors.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    divertors.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    divertors.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    divertors.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    divertors.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    divertors.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    divertors.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    divertors.midplane.description

    Verbose description

    • Data Type: STR_0D
    divertors.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    divertors.midplane.name

    Short string identifier

    • Data Type: STR_0D
    divertors.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    ec_launchers.beam[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    ec_launchers.beam[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    ec_launchers.beam[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].frequency.time"]
    ec_launchers.beam[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].identifier

    Beam identifier

    • Data Type: STR_0D
    ec_launchers.beam[:].launching_position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].launching_position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].launching_position.r_limit_max

    Major radius upper limit for the system

    • Units: m
    • Data Type: FLT_0D
    ec_launchers.beam[:].launching_position.r_limit_min

    Major radius lower limit for the system

    • Units: m
    • Data Type: FLT_0D
    ec_launchers.beam[:].launching_position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].mode

    Identifier for the main plasma wave mode excited by the EC beam. For the ordinary mode (O-mode), mode=1. For the extraordinary mode (X-mode), mode=-1

    • Data Type: INT_0D
    ec_launchers.beam[:].name

    Beam name

    • Data Type: STR_0D
    ec_launchers.beam[:].o_mode_fraction

    Fraction of EC beam power launched in ordinary (O) mode. If all power is launched in ordinary mode (O-mode), omodefraction = 1.0. If all power is launched in extraordinary mode (X-mode), omodefraction = 0.0

    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].phase.angle

    Rotation angle for the phase ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].phase.curvature

    Inverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "ec_launchers.beam[:].time"]
    ec_launchers.beam[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].power_launched.time"]
    ec_launchers.beam[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].spot.angle

    Rotation angle for the spot ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].spot.size

    Size of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "ec_launchers.beam[:].time"]
    ec_launchers.beam[:].steering_angle_pol

    Steering angle of the EC beam in the R,Z plane (from the -R axis towards the -Z axis), anglepol=atan2(-kZ,-kR), where kZ and k_R are the Z and R components of the mean wave vector in the EC beam

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].steering_angle_tor

    Steering angle of the EC beam away from the poloidal plane that is increasing towards the positive phi axis, angletor=arcsin(kphi/k), where k_phi is the component of the wave vector in the phi direction and k is the length of the wave vector. Here the term wave vector refers to the mean wave vector in the EC beam

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].time

    Time base used for launchingposition, omode_fraction, angle, spot and phase quantities

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ec_launchers.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ec_launchers.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ec_launchers.time"]
    ec_launchers.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.code.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ec_launchers.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ec_launchers.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ec_launchers.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ec_launchers.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ec_launchers.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ec_launchers.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ec_launchers.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ec_launchers.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    ec_launchers.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.phase.angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].beam.phase.angle.time"]
    ece.channel[:].beam.phase.angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.phase.curvature.data

    Data

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "ece.channel[:].beam.phase.curvature.time"]
    ece.channel[:].beam.phase.curvature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.spot.angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].beam.spot.angle.time"]
    ece.channel[:].beam.spot.angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.spot.size.data

    Data

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "ece.channel[:].beam.spot.size.time"]
    ece.channel[:].beam.spot.size.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].delta_position_suprathermal.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].frequency.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].frequency.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].harmonic.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].harmonic.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].harmonic.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    ece.channel[:].if_bandwidth

    Full-width of the Intermediate Frequency (IF) bandpass filter

    • Units: Hz
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    ece.channel[:].optical_depth.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].optical_depth.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].optical_depth.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].t_e_voltage.time"]
    ece.channel[:].t_e_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].t_e_voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].t_e_voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].t_e_voltage.time"]
    ece.channel[:].time

    Timebase for the processed dynamic data of this channel (outside of the beam structure)

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ece.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ece.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ece.time"]
    ece.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.code.repository

    URL of software repository

    • Data Type: STR_0D
    ece.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ece.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ece.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ece.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ece.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ece.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ece.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ece.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ece.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ece.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ece.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ece.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ece.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ece.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.polarizer[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].polarization_angle

    Alignment angle of the polarizer in the (x1,x2) plane. Electric fields parallel to the polarizer angle will be reflected. The angle is defined with respect to the x1 unit vector, positive in the counter-clockwise direction when looking towards the plasma

    • Units: rad
    • Data Type: FLT_0D
    ece.polarizer[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["ece.psi_normalization.time"]
    ece.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["ece.psi_normalization.time"]
    ece.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.t_e_central.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.t_e_central.rho_tor_norm

    Normalised toroidal flux coordinate of the measurement

    • Data Type: FLT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.t_e_central.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.t_e_central.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.t_e_central.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_profiles.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_profiles.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.time"]
    edge_profiles.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ggd[:].a_field_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].a_field_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].a_field_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].a_field_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].a_field_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].e_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].e_field[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.density[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.temperature[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].z_average[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].j_anomalous[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_anomalous[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_anomalous[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_heat_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_heat_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_inertial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_inertial[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].j_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].j_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_total[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].n_i_total_over_n_e[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].n_i_total_over_n_e[:].values", "1...N"]
    edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].n_i_total_over_n_e[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].phi_potential[:].values", "1...N"]
    edge_profiles.ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_thermal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_thermal[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_thermal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_thermal[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_thermal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].t_i_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].t_i_average[:].values", "1...N"]
    edge_profiles.ggd[:].t_i_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].t_i_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].t_i_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.ggd[:].zeff[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].zeff[:].values", "1...N"]
    edge_profiles.ggd[:].zeff[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].zeff[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].zeff[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd_fast[:].electrons.density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.density[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: m^-3
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: J
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: m^-3
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element"]
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element"]
    edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_profiles.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_profiles.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_profiles.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_profiles.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_profiles.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_profiles.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].q

    Safety factor

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.statistics[:].quantity_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].quantity_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].quantity_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics value

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path

    For Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3)

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].value

    Value of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.statistics[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.statistics[:].time_width

    Width of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.statistics[:].uq_input_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].uq_input_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].uq_input_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    edge_profiles.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.time"]
    edge_profiles.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    edge_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_sources.time"]
    edge_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element"]
    edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element"]
    edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].current[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].current[:].values", "1...N"]
    edge_sources.source[:].ggd[:].current[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].current[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].current[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].electrons.energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].electrons.energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].electrons.energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].electrons.particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].electrons.particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].electrons.particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].total_ion_energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].total_ion_energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.source[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_transport.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_transport.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_transport.time"]
    edge_transport.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element"]
    edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element"]
    edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_transport.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_transport.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_transport.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_transport.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_transport.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_transport.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.model[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.model[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.model[:].code.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.model[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["edge_transport.model[:].code.output_flag.time"]
    edge_transport.model[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.model[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.model[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.model[:].flux_multiplier

    Multiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2

    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].conductivity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].conductivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].conductivity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W.m^-2
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    em_coupling.active_coils

    List of URIs of the active coils considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_active.coil"]
    em_coupling.b_field_pol_probes

    List of URIs of the poloidal field probes considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["magnetics.b_field_pol_probe"]
    em_coupling.b_field_pol_probes_active

    Poloidal field coupling from active coils to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["magnetics.b_field_pol_probe", "em_coupling.active_coils"]
    em_coupling.b_field_pol_probes_passive

    Poloidal field coupling from passive loops to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.b_field_pol_probes", "em_coupling.passive_loops"]
    em_coupling.b_field_pol_probes_plasma

    Poloidal field coupling from plasma elements to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.b_field_pol_probes", "em_coupling.plasma_elements"]
    em_coupling.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.code.library[:].name

    Name of software

    • Data Type: STR_0D
    em_coupling.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    em_coupling.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["em_coupling.time"]
    em_coupling.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.code.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].columns_uri

    List of URIs corresponding to the columns (2nd dimension) of the coupling matrix. See examples above (rows_uri)

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.coupling_matrix[:].data

    Coupling matrix

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.coupling_matrix[:].rows_uri", "em_coupling.coupling_matrix[:].columns_uri"]
    em_coupling.coupling_matrix[:].name

    Name of this coupling matrix

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].quantity.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].quantity.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.coupling_matrix[:].quantity.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].rows_uri

    List of URIs corresponding to the rows (1st dimension) of the coupling matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector, it is sufficient to give a insgle uri, the one of the vector with the impliicit notation (:), e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.flux_loops

    List of URIs of the flux loops considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["magnetics.flux_loop"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element"]
    em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    em_coupling.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    em_coupling.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    em_coupling.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    em_coupling.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    em_coupling.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.mutual_active_active

    Mutual inductance coupling from active coils to active coils

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.active_coils", "em_coupling.active_coils"]
    em_coupling.mutual_loops_active

    Mutual inductance coupling from active coils to flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.active_coils"]
    em_coupling.mutual_loops_passive

    Mutual inductance coupling from passive loops to flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.passive_loops"]
    em_coupling.mutual_loops_plasma

    Mutual inductance from plasma elements to poloidal flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.plasma_elements"]
    em_coupling.mutual_passive_active

    Mutual inductance coupling from active coils to passive loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.passive_loops", "em_coupling.active_coils"]
    em_coupling.mutual_passive_passive

    Mutual inductance coupling from passive loops to passive loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.passive_loops", "em_coupling.passive_loops"]
    em_coupling.mutual_plasma_active

    Mutual inductance coupling from active coils to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.active_coils"]
    em_coupling.mutual_plasma_passive

    Mutual inductance coupling from passive loops to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.passive_loops"]
    em_coupling.mutual_plasma_plasma

    Mutual inductance coupling from plasma elements to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.plasma_elements"]
    em_coupling.passive_loops

    List of URIs of the passive loops considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_passive.loop"]
    em_coupling.plasma_elements

    List of URIs of the plasma elements considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_plasma.element"]
    em_coupling.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.code.library[:].name

    Name of software

    • Data Type: STR_0D
    equilibrium.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    equilibrium.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["equilibrium.time"]
    equilibrium.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.code.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    equilibrium.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    equilibrium.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    equilibrium.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    equilibrium.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    equilibrium.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    equilibrium.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    equilibrium.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary.active_limiter_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.active_limiter_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation

    Elongation of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation_lower

    Elongation (lower half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation_upper

    Elongation (upper half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.minor_radius

    Minor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary.outline.r"]
    equilibrium.time_slice[:].boundary.ovality

    Ovality of the plasma boundary [MXH c1]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.psi

    Value of the poloidal flux at which the boundary is taken

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.psi_norm

    Value of the normalised poloidal flux at which the boundary is taken (typically 99.x %), the flux being normalised to its value at the separatrix

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness

    Squareness of the plasma boundary [MXH -s2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_lower_inner

    Lower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_lower_outer

    Lower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_upper_inner

    Upper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_upper_outer

    Upper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.tilt

    Tilt of the plasma boundary [MXH c0]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity

    Triangularity of the plasma boundary [MXH sin(s1)]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity_lower

    Lower triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity_upper

    Upper triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.twist

    Twist of the plasma boundary [MXH c2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.type

    0 (limiter) or 1 (diverted)

    • Data Type: INT_0D
    equilibrium.time_slice[:].boundary.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.distance_inner_outer

    Distance between the inner and outer separatrices, in the major radius direction, at the plasma outboard and at the height corresponding to the maximum R for the inner separatrix.

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary_secondary_separatrix.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r"]
    equilibrium.time_slice[:].boundary_secondary_separatrix.psi

    Value of the poloidal flux at the separatrix

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.active_limiter_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.active_limiter_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.distance

    Distance to the plasma boundary

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.dr_dz_zero_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.dr_dz_zero_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation

    Elongation of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation_lower

    Elongation (lower half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation_upper

    Elongation (upper half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].angle

    Angle measured clockwise from radial cylindrical vector (grad R) to gap vector (pointing away from reference point)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].identifier

    Identifier of the gap

    • Data Type: STR_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].name

    Name of the gap

    • Data Type: STR_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].r

    Major radius of the reference point

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].value

    Value of the gap, i.e. distance between the reference point and the separatrix along the gap direction

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].z

    Height of the reference point

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.minor_radius

    Minor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary_separatrix.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary_separatrix.outline.r"]
    equilibrium.time_slice[:].boundary_separatrix.psi

    Value of the poloidal flux at the separatrix

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_lower_inner

    Lower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_lower_outer

    Lower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_upper_inner

    Upper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_upper_outer

    Upper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity

    Triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_inner

    Inner triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_lower

    Lower triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_minor

    Minor triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_outer

    Outer triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_upper

    Upper triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.type

    0 (limiter) or 1 (diverted)

    • Data Type: INT_0D
    equilibrium.time_slice[:].boundary_separatrix.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.measured

    Measured value

    • Units: T.m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T.m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.chi_squared_reduced

    Sum of the chi_squared of all constraints used for the equilibrium reconstruction, divided by the number of degrees of freedom of the identification model

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.constraints_n

    Number of constraints used (i.e. having a non-zero weight)

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.measured

    Measured value

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].measured

    Measured value

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].measured

    Measured value

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.freedom_degrees_n

    Number of degrees of freedom of the identification model

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.ip.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.ip.measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.ip.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].measured

    Measured value

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].measured

    Measured value

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.j_tor[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].measured

    Measured value

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.n_e[:].measured

    Measured value

    • Units: m^-3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.n_e[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].measured

    Measured value

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pf_current[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pressure[:].measured

    Measured value

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pressure[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].measured

    Measured value

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.q[:].measured

    Measured value

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.q[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_r

    Squared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_z

    Squared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_measured.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_measured.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.strike_point[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].chi_squared_r

    Squared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].chi_squared_z

    Squared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_measured.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_measured.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.x_point[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_value

    Value of the residual deviation between the left and right hand side of the Grad Shafranov equation, evaluated as per gradshafranovdeviation_expression

    • Units: mixed
    • Data Type: FLT_0D
    equilibrium.time_slice[:].convergence.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.result.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.result.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.result.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2", "1...3", "1...3"]
    equilibrium.time_slice[:].coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2", "1...3", "1...3"]
    equilibrium.time_slice[:].coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].ggd[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_r[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_tor[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_z[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].j_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].j_parallel[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].j_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].j_tor[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].j_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].phi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].phi[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].phi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].phi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].phi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].psi[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].r[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].theta[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].theta[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].theta[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].theta[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].theta[:].values

    One scalar value is provided per element in the grid subset.

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].z[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].global_quantities.area

    Area of the LCFS poloidal cross section

    • Units: m^2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_normal

    Normalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_pol

    Poloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_tor

    Toroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.r

    Major radius of the current center, defined as integral over the poloidal cross section of (j_torrdS) / Ip

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.velocity_z

    Vertical velocity of the current center

    • Units: m.s^-1
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.z

    Height of the current center, defined as integral over the poloidal cross section of (j_torzdS) / Ip

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.energy_mhd

    Plasma energy content = 3/2 * int(p,dV) with p being the total pressure (thermal + fast particles) [J]. Time-dependent; Scalar

    • Units: J
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.ip

    Plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.length_pol

    Poloidal length of the magnetic surface

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.li_3

    Internal inductance

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.b_field_tor

    Total toroidal magnetic field at the magnetic axis

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.r

    Major radius of the magnetic axis

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.z

    Height of the magnetic axis

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.plasma_inductance

    Plasma inductance 2 Emagnetic/Ip^2, where Emagnetic = 1/2 * int(psi.j_tor.dS) (integral over the plasma poloidal cross-section)

    • Units: H
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.plasma_resistance

    Plasma resistance = int(e_field.j.dV) / Ip^2

    • Units: ohm
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_axis

    Poloidal flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_boundary

    Poloidal flux at the selected plasma boundary

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_external_average

    Average (over the plasma poloidal cross section) plasma poloidal magnetic flux produced by all external circuits (CS and PF coils, eddy currents, VS in-vessel coils), given by the following formula : int(psiexternal.jtor.dS) / Ip

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_95

    q at the 95% poloidal flux surface (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_axis

    q at the magnetic axis

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.psi

    Minimum q position in poloidal flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.psi_norm

    Minimum q position in normalised poloidal flux

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.rho_tor_norm

    Minimum q position in normalised toroidal flux coordinate

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.value

    Minimum q value

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.rho_tor_boundary

    Toroidal flux coordinate at the selected plasma boundary

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.v_external

    External voltage, i.e. time derivative of psiexternalaverage (with a minus sign : - dpsiexternalaverage/dtime)

    • Units: V
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.volume

    Total plasma volume

    • Units: m^3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].profiles_1d.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_average

    Flux surface averaged modulus of B (always positive, irrespective of the sign convention for the B-field direction).

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_max

    Maximum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_min

    Minimum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.beta_pol

    Poloidal beta profile. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.darea_dpsi

    Radial derivative of the cross-sectional area of the flux surface with respect to psi

    • Units: m^2.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.darea_drho_tor

    Radial derivative of the cross-sectional area of the flux surface with respect to rho_tor

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dpressure_dpsi

    Derivative of pressure w.r.t. psi

    • Units: Pa.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dpsi_drho_tor

    Derivative of Psi with respect to Rho_Tor

    • Units: Wb/m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dvolume_dpsi

    Radial derivative of the volume enclosed in the flux surface with respect to Psi

    • Units: m^3.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dvolume_drho_tor

    Radial derivative of the volume enclosed in the flux surface with respect to Rho_Tor

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.elongation

    Elongation

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.f

    Diamagnetic function (F=R B_Phi)

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.f_df_dpsi

    Derivative of F w.r.t. Psi, multiplied with F

    • Units: T^2.m^2/Wb
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.fsa_bp

    Flux surface averaged Bp

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm1

    Flux surface averaged 1/R^2

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm10

    Flux surface averaged R^2

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm2

    Flux surface averaged |gradrhotor|^2/R^2

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm3

    Flux surface averaged |gradrhotor|^2

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm4

    Flux surface averaged 1/B^2

    • Units: T^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm5

    Flux surface averaged B^2

    • Units: T^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm6

    Flux surface averaged |gradrhotor|^2/B^2

    • Units: T^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm7

    Flux surface averaged |gradrhotor|

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm8

    Flux surface averaged R

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm9

    Flux surface averaged 1/R

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.j_parallel

    Flux surface averaged approximation to parallel current density = average(j.B) / B0, where B0 = /vacuumtoroidalfield/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.j_tor

    Flux surface averaged toroidal current density = average(j_tor/R) / average(1/R)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.mass_density

    Mass density

    • Units: kg.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.psi

    Poloidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_1d.psi_norm

    Normalised poloidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.r_inboard

    Radial coordinate (major radius) on the inboard side of the magnetic axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.r_outboard

    Radial coordinate (major radius) on the outboard side of the magnetic axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_tor

    Toroidal flux coordinate = sqrt(phi/(pi*b0)), where the toroidal flux, phi, corresponds to timeslice/profiles1d/phi, the toroidal magnetic field, b0, corresponds to vacuumtoroidalfield/b0 and pi can be found in the IMAS constants

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_volume_norm

    Normalised square root of enclosed volume (radial coordinate). The normalizing value is the enclosed volume at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_lower_inner

    Lower inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_lower_outer

    Lower outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_upper_inner

    Upper inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_upper_outer

    Upper outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.trapped_fraction

    Trapped particle fraction

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.triangularity_lower

    Lower triangularity w.r.t. magnetic axis

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.triangularity_upper

    Upper triangularity w.r.t. magnetic axis

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.volume

    Volume enclosed in the flux surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_r

    R component of the poloidal magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_tor

    Toroidal component of the magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_z

    Z component of the poloidal magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].j_parallel

    Defined as (j.B)/B0 where j and B are the current density and magnetic field vectors and B0 is the (signed) vacuum toroidal magnetic field strength at the geometric reference point (R0,Z0). It is formally not the component of the plasma current density parallel to the magnetic field

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].j_tor

    Toroidal plasma current density

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].psi

    Values of the poloidal flux at the grid in the poloidal plane

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].theta

    Values of the poloidal angle on the grid

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].profiles_2d[:].type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    equilibrium.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time"]
    equilibrium.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    ferritic.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ferritic.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ferritic.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ferritic.time"]
    ferritic.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.code.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element"]
    ferritic.grid_ggd.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].dimension

    Space dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].dimension

    Dimension of the object

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element"]
    ferritic.grid_ggd.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ferritic.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ferritic.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ferritic.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ferritic.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ferritic.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ferritic.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ferritic.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ferritic.object[:].axisymmetric[:].annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].arcs_of_circle.r"]
    ferritic.object[:].axisymmetric[:].arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].axisymmetric[:].arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].arcs_of_circle.r"]
    ferritic.object[:].axisymmetric[:].geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    ferritic.object[:].axisymmetric[:].oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].axisymmetric[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].outline.r"]
    ferritic.object[:].axisymmetric[:].rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].centroid.x

    List of X coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].centroid.y

    List of Y coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].centroid.z

    List of Z coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].ggd_object_index

    Index of GGD volumic object corresponding to each element. Refers to the array /gridggd/space(1)/objectsper_dimension(4)/object

    • Data Type: INT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].permeability_table_index

    Index of permeability table to be used for each element. If not allocated or if an element is equal to EMPTYINT, use the sibling saturated relative permeability instead ../relativepermeability, for that element

    • Data Type: INT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].saturated_relative_permeability

    Saturated relative magnetic permeability of each element

    • Units: H.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_r

    R component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_tor

    Toroidal component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_z

    Z component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_r

    R component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_tor

    Toroidal component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_z

    Z component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ferritic.object[:].volume

    Volume of each element of this object

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.permeability_table[:].b_field

    Array of magnetic field values, for each of which the relative permeability is given

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.permeability_table[:].description

    Description of this table

    • Data Type: STR_0D
    ferritic.permeability_table[:].name

    Name of this table

    • Data Type: STR_0D
    ferritic.permeability_table[:].relative_permeability

    Relative permeability as a function of the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["ferritic.permeability_table[:].b_field"]
    ferritic.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.b_field_z.data

    Data

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "focs.b_field_z.time"]
    focs.b_field_z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.b_field_z.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    focs.b_field_z.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["focs.b_field_z.time"]
    focs.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.code.library[:].name

    Name of software

    • Data Type: STR_0D
    focs.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    focs.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["focs.time"]
    focs.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.code.repository

    URL of software repository

    • Data Type: STR_0D
    focs.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["focs.current.time"]
    focs.current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    focs.current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["focs.current.time"]
    focs.fibre_length

    Spun fibre length on the vacuum vessel

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.beat_length

    Linear beat length

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.id

    ID of the fibre, e.g. commercial reference

    • Data Type: STR_0D
    focs.fibre_properties.spun

    Spun period

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.spun_initial_azimuth

    Spun fibre initial azimuth

    • Units: rad
    • Data Type: FLT_0D
    focs.fibre_properties.twist

    Twist period

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.verdet_constant

    Verdet constant

    • Units: rad.T^-1.m^-1
    • Data Type: FLT_0D
    focs.id

    ID of the FOCS

    • Data Type: STR_0D
    focs.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    focs.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    focs.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    focs.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    focs.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    focs.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    focs.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    focs.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    focs.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    focs.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    focs.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    focs.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    focs.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    focs.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    focs.name

    Name of the FOCS

    • Data Type: STR_0D
    focs.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["focs.outline.r"]
    focs.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["focs.outline.r"]
    focs.stokes_initial.s0

    S0 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s1

    S1 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s2

    S2 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s3

    S3 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s0

    S0 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s1

    S1 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s2

    S2 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s3

    S3 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    focs.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gas_injection.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gas_injection.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gas_injection.time"]
    gas_injection.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.code.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gas_injection.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gas_injection.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gas_injection.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gas_injection.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gas_injection.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gas_injection.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gas_injection.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gas_injection.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.pipe[:].flow_rate.time"]
    gas_injection.pipe[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.pipe[:].identifier

    ID of the injection pipe

    • Data Type: STR_0D
    gas_injection.pipe[:].length

    Pipe length

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].name

    Name of the injection pipe

    • Data Type: STR_0D
    gas_injection.pipe[:].second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    gas_injection.pipe[:].second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_injection.pipe[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    gas_injection.pipe[:].valve_indices

    Indices (from the ../../valve array of structure) of the valve(s) that are feeding this pipe

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    gas_injection.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].electron_rate.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].electron_rate.time"]
    gas_injection.valve[:].electron_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].flow_rate.time"]
    gas_injection.valve[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].flow_rate_max

    Maximum flow rate of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_0D
    gas_injection.valve[:].flow_rate_min

    Minimum flow rate of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_0D
    gas_injection.valve[:].identifier

    ID of the valve

    • Data Type: STR_0D
    gas_injection.valve[:].name

    Name of the valve

    • Data Type: STR_0D
    gas_injection.valve[:].pipe_indices

    Indices (from the ../../pipe array of structure) of the pipe(s) that are fed by this valve

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].response_curve.flow_rate

    Flow rate at the exit of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].response_curve.voltage"]
    gas_injection.valve[:].response_curve.voltage

    Voltage applied to open the valve

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_injection.valve[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    gas_injection.valve[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].voltage.time"]
    gas_injection.valve[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gas_pumping.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gas_pumping.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gas_pumping.time"]
    gas_pumping.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.code.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.duct[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_pumping.duct[:].flow_rate.time"]
    gas_pumping.duct[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.duct[:].identifier

    ID of the pumping duct

    • Data Type: STR_0D
    gas_pumping.duct[:].name

    Name of the pumping duct

    • Data Type: STR_0D
    gas_pumping.duct[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_pumping.duct[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_pumping.duct[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_pumping.duct[:].species[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_pumping.duct[:].species[:].flow_rate.time"]
    gas_pumping.duct[:].species[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.duct[:].species[:].label

    String identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)

    • Data Type: STR_0D
    gas_pumping.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gas_pumping.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gas_pumping.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gas_pumping.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gas_pumping.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gas_pumping.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gas_pumping.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gas_pumping.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gas_pumping.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gyrokinetics_local.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gyrokinetics_local.time"]
    gyrokinetics_local.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.code.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.collisions.collisionality_norm

    Normalised collisionality between two species

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.species"]
    gyrokinetics_local.flux_surface.b_field_tor_sign

    Sign of the toroidal magnetic field

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dc_dr_minor_norm

    Derivative of the 'c' shape coefficients with respect to rminornorm

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.flux_surface.shape_coefficients_c"]
    gyrokinetics_local.flux_surface.delongation_dr_minor_norm

    Derivative of the elongation with respect to rminornorm

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dgeometric_axis_r_dr_minor

    Derivative of the major radius of the surface geometric axis with respect to r_minor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dgeometric_axis_z_dr_minor

    Derivative of the height of the surface geometric axis with respect to r_minor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.ds_dr_minor_norm

    Derivative of the 's' shape coefficients with respect to rminornorm

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.flux_surface.shape_coefficients_s"]
    gyrokinetics_local.flux_surface.elongation

    Elongation

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.ip_sign

    Sign of the plasma current

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.magnetic_shear_r_minor

    Magnetic shear, defined as rminornorm/q . dq/drminornorm (different definition from the equilibrium IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.pressure_gradient_norm

    Normalised pressure gradient (derivative with respect to rminornorm)

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.q

    Safety factor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.r_minor_norm

    Normalised minor radius of the flux surface of interest = 1/2 * (max(R) - min(R))/L_ref

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.shape_coefficients_c

    'c' coefficients in the formula defining the shape of the flux surface

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.flux_surface.shape_coefficients_s

    's' coefficients in the formula defining the shape of the flux surface

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.linear.wavevector[:].binormal_wavevector_norm

    Normalised binormal component of the wavevector

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol

    Poloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_parity

    Parity of the perturbed parallel vector potential with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_weight

    Amplitude of the perturbed parallel vector potential normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_parity

    Parity of the perturbed parallel magnetic field with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_weight

    Amplitude of the perturbed parallel magnetic field normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_parity

    Parity of the perturbed electrostatic potential with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_weight

    Amplitude of the perturbed electrostatic potential normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].frequency_norm

    Frequency

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_norm

    Growth rate

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_tolerance

    Relative tolerance on the growth rate (convergence of the simulation)

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].initial_value_run

    Flag = 1 if this is an initial value run, 0 for an eigenvalue run

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].poloidal_turns

    Number of poloidal turns considered in the flux-tube simulation

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm

    Normalised time of the gyrokinetic simulation

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.linear.wavevector[:].radial_wavevector_norm

    Normalised radial component of the wavevector

    • Data Type: FLT_0D
    gyrokinetics_local.model.adiabatic_electrons

    Flag = 1 if electrons are adiabatic, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_energy_conservation

    Flag = 1 if the collision operator conserves energy, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_finite_larmor_radius

    Flag = 1 if finite larmor radius effects are retained in the collision operator, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_momentum_conservation

    Flag = 1 if the collision operator conserves momentum, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_pitch_only

    Flag = 1 if only pitch-angle scattering is retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_a_field_parallel

    Flag = 1 if fluctuations of the parallel vector potential are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_b_field_parallel

    Flag = 1 if fluctuations of the parallel magnetic field are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_centrifugal_effects

    Flag = 1 if centrifugal effects are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_coriolis_drift

    Flag = 1 if Coriolis drift is included, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_full_curvature_drift

    Flag = 1 if all contributions to the curvature drift are included (including betaprime), 0 otherwise. Neglecting the betaprime contribution (Flag=0) is only recommended together with the neglect of parallel magnetic field fluctuations

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.angle_pol

    Poloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.binormal_wavevector_norm

    Array of normalised binormal wavevectors

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.non_linear.fields_4d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_4d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_4d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_3d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_intensity_3d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_intensity_3d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_zonal_2d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_zonal_2d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_zonal_2d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.quasi_linear

    Flag = 1 if the non-linear fluxes are in fact calculated by a quasi-linear model, 0 if non-linear

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.radial_wavevector_norm

    Array of normalised radial wavevectors

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.time_interval_norm

    Normalised time interval used to average fluxes in non-linear runs

    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    gyrokinetics_local.non_linear.time_norm

    Normalised time of the gyrokinetic simulation

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.normalizing_quantities.b_field_tor

    Toroidal magnetic field at major radius r

    • Units: T
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.n_e

    Electron density at outboard equatorial midplane of the flux surface (angle_pol = 0)

    • Units: m^-3
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.r

    Major radius of the flux surface of interest, defined as (min(R)+max(R))/2

    • Units: m
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.t_e

    Electron temperature at outboard equatorial midplane of the flux surface (angle_pol = 0)

    • Units: eV
    • Data Type: FLT_0D
    gyrokinetics_local.species[:].charge_norm

    Normalised charge

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].density_log_gradient_norm

    Normalised logarithmic gradient (with respect to rminornorm) of the density

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].density_norm

    Normalised density

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].mass_norm

    Normalised mass

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].potential_energy_gradient_norm

    Effective potential energy determining the poloidal variation of the species background density

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species_all.angle_pol"]
    gyrokinetics_local.species[:].potential_energy_norm

    Normalised gradient (with respect to rminornorm) of the effective potential energy

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species_all.angle_pol"]
    gyrokinetics_local.species[:].temperature_log_gradient_norm

    Normalised logarithmic gradient (with respect to rminornorm) of the temperature

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].temperature_norm

    Normalised temperature

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].velocity_tor_gradient_norm

    Normalised gradient (with respect to rminornorm) of the toroidal velocity

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.angle_pol

    Poloidal angle grid, from -pi to pi, on which the species dependent effective potential energy (which determines the poloidal variation of the density) is expressed. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.species_all.beta_reference

    Reference plasma beta (see detailed documentation at the root of the IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.debye_length_norm

    Debye length computed from the reference quantities (see detailed documentation at the root of the IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.shearing_rate_norm

    Normalised ExB shearing rate (for non-linear runs only)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.velocity_tor_norm

    Normalised toroidal velocity of species (all species are assumed to have a purely toroidal velocity with a common toroidal angular frequency)

    • Data Type: FLT_0D
    gyrokinetics_local.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    hard_x_rays.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].aperture[:].outline.x1"]
    hard_x_rays.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    hard_x_rays.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].detector.outline.x1"]
    hard_x_rays.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].energy_band[:].energies"]
    hard_x_rays.channel[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.channel[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    hard_x_rays.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].filter_window[:].outline.x1"]
    hard_x_rays.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].filter_window[:].wavelengths"]
    hard_x_rays.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    hard_x_rays.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    hard_x_rays.channel[:].radiance.data

    Data

    • Units: (photons).s^-1.m^-2.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "hard_x_rays.channel[:].radiance.time"]
    hard_x_rays.channel[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].radiance.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    hard_x_rays.channel[:].radiance.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.channel[:].radiance.time"]
    hard_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    hard_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    hard_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.time"]
    hard_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.emissivity_profile_1d[:].emissivity

    Radial profile of the plasma emissivity in this energy band

    • Units: (photons).m^-3.str^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].rho_tor_norm", "hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].half_width_external

    External (towards separatrix) half width of the emissivity peak (in normalised toroidal flux)

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].half_width_internal

    Internal (towards magnetic axis) half width of the emissivity peak (in normalised toroidal flux)

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.emissivity_profile_1d[:].peak_position

    Normalised toroidal flux coordinate position at which the emissivity peaks

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].rho_tor_norm

    Normalised toroidal flux coordinate grid

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.emissivity_profile_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.emissivity_profile_1d[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.emissivity_profile_1d[:].validity_timed

    Indicator of the validity of the emissivity profile data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    hard_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    hard_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    hard_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    hard_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    hard_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    hard_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    hard_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.coupling

    Coupling efficiency of launched microwave power to the plasma

    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    ic_antennas.antenna[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].frequency.time"]
    ic_antennas.antenna[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].identifier

    Identifier of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].coupling_resistance.data

    Data

    • Units: ohm
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].coupling_resistance.time"]
    ic_antennas.antenna[:].module[:].coupling_resistance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].amplitude.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].current[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].current[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].current[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].current[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].current[:].phase.time"]
    ic_antennas.antenna[:].module[:].current[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].current[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].current[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].frequency.time"]
    ic_antennas.antenna[:].module[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].identifier

    Identifier of the module

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].capacitance.data

    Data

    • Units: F
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time"]
    ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].matching_element[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].matching_element[:].phase.time"]
    ic_antennas.antenna[:].module[:].matching_element[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].matching_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ic_antennas.antenna[:].module[:].matching_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].name

    Name of the module

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].phase_forward.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].phase_forward.time"]
    ic_antennas.antenna[:].module[:].phase_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].phase_reflected.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].phase_reflected.time"]
    ic_antennas.antenna[:].module[:].phase_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_forward.time"]
    ic_antennas.antenna[:].module[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_launched.time"]
    ic_antennas.antenna[:].module[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_reflected.time"]
    ic_antennas.antenna[:].module[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].amplitude.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].pressure[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].pressure[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].pressure[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].pressure[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].pressure[:].phase.time"]
    ic_antennas.antenna[:].module[:].pressure[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].pressure[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].pressure[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].current.time"]
    ic_antennas.antenna[:].module[:].strap[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].distance_to_conductor

    Distance to conducting wall or other conductor behind the antenna strap

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].phase.time"]
    ic_antennas.antenna[:].module[:].strap[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].width_tor

    Width of strap in the toroidal direction

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].voltage[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].voltage[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].voltage[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].voltage[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].voltage[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].voltage[:].phase.time"]
    ic_antennas.antenna[:].module[:].voltage[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].voltage[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].name

    Name of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    ic_antennas.antenna[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_forward.time"]
    ic_antennas.antenna[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_launched.time"]
    ic_antennas.antenna[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_reflected.time"]
    ic_antennas.antenna[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].m_pol

    Poloidal mode numbers, used to describe the spectrum of the antenna current. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/z

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].n_tor

    Toroidal mode numbers, used to describe the spectrum of the antenna current. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].spectrum

    Spectrum of the total surface current on the antenna strap and passive components expressed in poloidal and toroidal modes

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["ic_antennas.antenna[:].surface_current[:].m_pol", "ic_antennas.antenna[:].surface_current[:].n_tor"]
    ic_antennas.antenna[:].surface_current[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ic_antennas.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ic_antennas.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ic_antennas.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ic_antennas.time"]
    ic_antennas.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.code.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ic_antennas.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ic_antennas.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ic_antennas.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ic_antennas.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ic_antennas.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ic_antennas.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ic_antennas.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ic_antennas.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    ic_antennas.power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.power_launched.time"]
    ic_antennas.power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.reference_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.reference_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    interferometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r", "interferometer.channel[:].n_e.time"]
    interferometer.channel[:].n_e.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r"]
    interferometer.channel[:].n_e.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r"]
    interferometer.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line.time"]
    interferometer.channel[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.channel[:].n_e_line.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line.time"]
    interferometer.channel[:].n_e_line_average.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line_average.time"]
    interferometer.channel[:].n_e_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.channel[:].n_e_line_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line_average.time"]
    interferometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    interferometer.channel[:].path_length_variation.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].path_length_variation.time"]
    interferometer.channel[:].path_length_variation.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].fringe_jump_correction

    Signed number of 2pi phase corrections applied to remove a fringe jump, for each time slice on which a correction has been made

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].wavelength[:].fringe_jump_correction_times"]
    interferometer.channel[:].wavelength[:].fringe_jump_correction_times

    List of time slices of the pulse on which a fringe jump correction has been made

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].phase_corrected.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].wavelength[:].phase_corrected.time"]
    interferometer.channel[:].wavelength[:].phase_corrected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].phase_to_n_e_line

    Conversion factor to be used to convert phase into line density for this wavelength

    • Units: m^-2.rad^-1
    • Data Type: FLT_0D
    interferometer.channel[:].wavelength[:].value

    Wavelength value

    • Units: m
    • Data Type: FLT_0D
    interferometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    interferometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    interferometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["interferometer.time"]
    interferometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.electrons_n.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["interferometer.electrons_n.time"]
    interferometer.electrons_n.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.electrons_n.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.electrons_n.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.electrons_n.time"]
    interferometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    interferometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    interferometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    interferometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    interferometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    interferometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    interferometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    interferometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    interferometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    interferometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    interferometer.n_e_volume_average.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.n_e_volume_average.time"]
    interferometer.n_e_volume_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.n_e_volume_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.n_e_volume_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.n_e_volume_average.time"]
    interferometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.code.library[:].name

    Name of software

    • Data Type: STR_0D
    iron_core.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    iron_core.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["iron_core.time"]
    iron_core.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.code.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    iron_core.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    iron_core.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    iron_core.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    iron_core.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    iron_core.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    iron_core.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    iron_core.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    iron_core.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    iron_core.segment[:].b_field

    Array of magnetic field values, for each of which the relative permeability is given

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.arcs_of_circle.r"]
    iron_core.segment[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.arcs_of_circle.r"]
    iron_core.segment[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    iron_core.segment[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.outline.r"]
    iron_core.segment[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].identifier

    ID of the segment

    • Data Type: STR_0D
    iron_core.segment[:].magnetisation_r.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].magnetisation_r.time"]
    iron_core.segment[:].magnetisation_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].magnetisation_z.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].magnetisation_z.time"]
    iron_core.segment[:].magnetisation_z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].name

    Name of the segment

    • Data Type: STR_0D
    iron_core.segment[:].permeability_relative

    Relative permeability of the iron segment

    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].b_field"]
    iron_core.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.code.library[:].name

    Name of software

    • Data Type: STR_0D
    langmuir_probes.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    langmuir_probes.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.time"]
    langmuir_probes.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.code.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.embedded[:].b_field_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].b_field_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].b_field_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].distance_separatrix_midplane.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].distance_separatrix_midplane.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].fluence.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].fluence.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].fluence.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].heat_flux_parallel.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].heat_flux_parallel.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].heat_flux_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].identifier

    ID of the probe

    • Data Type: STR_0D
    langmuir_probes.embedded[:].ion_saturation_current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].ion_saturation_current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].ion_saturation_current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_parallel_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_skew.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_skew.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_skew.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.embedded[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].n_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].n_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].name

    Name of the probe

    • Data Type: STR_0D
    langmuir_probes.embedded[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].surface_area

    Area of the probe surface exposed to the plasma (use when assuming constant effective collection area)

    • Units: m^2
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].surface_area_effective.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].surface_area_effective.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].surface_area_effective.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.embedded[:].v_floating.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_floating.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating_sigma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_floating_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_plasma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_plasma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_plasma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.equilibrium_id.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    langmuir_probes.equilibrium_id.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.data_entry.run

    Run number

    • Data Type: INT_0D
    langmuir_probes.equilibrium_id.data_entry.user

    Username

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.name

    IDS name

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.occurrence

    IDS occurrence

    • Data Type: INT_0D
    langmuir_probes.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    langmuir_probes.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    langmuir_probes.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    langmuir_probes.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    langmuir_probes.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    langmuir_probes.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    langmuir_probes.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    langmuir_probes.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    langmuir_probes.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    langmuir_probes.midplane.description

    Verbose description

    • Data Type: STR_0D
    langmuir_probes.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    langmuir_probes.midplane.name

    Short string identifier

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].identifier

    ID of the probe

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].name

    Name of the probe

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity

    Indicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity_timed

    Indicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].n_e.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].n_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.validity

    Indicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].position_average.validity_timed

    Indicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].time

    Time of maximum penetration of the probe during a given plunge

    • Units: s
    • Data Type: FLT_0D
    langmuir_probes.reciprocating[:].plunge[:].time_within_plunge

    Time vector for describing the dynamics within the plunge

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].surface_area

    Area of the surface exposed to the plasma of each collector (constant assuming negligible dependence on e.g. the magnetic field line angle)

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].collector"]
    langmuir_probes.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    lh_antennas.antenna[:].distance_to_antenna

    Radial distance to the antenna mouth (grid for the electron density profile). 0 at antenna mouth, increasing towards the plasma

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    lh_antennas.antenna[:].efficiency.coupling

    Coupling efficiency of launched microwave power to the plasma

    • Data Type: FLT_0D
    lh_antennas.antenna[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    lh_antennas.antenna[:].frequency

    Frequency

    • Units: Hz
    • Data Type: FLT_0D
    lh_antennas.antenna[:].identifier

    Identifier of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    lh_antennas.antenna[:].model_name

    Name of the antenna model used for antenna spectrum computation

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].identifier

    Identifier of the module

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].name

    Name of the module

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].phase.time"]
    lh_antennas.antenna[:].module[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_forward.time"]
    lh_antennas.antenna[:].module[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_launched.time"]
    lh_antennas.antenna[:].module[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_reflected.time"]
    lh_antennas.antenna[:].module[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].reflection_coefficient.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].reflection_coefficient.time"]
    lh_antennas.antenna[:].module[:].reflection_coefficient.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "lh_antennas.antenna[:].n_e.time"]
    lh_antennas.antenna[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].n_parallel_peak.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].n_parallel_peak.time"]
    lh_antennas.antenna[:].n_parallel_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].name

    Name of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    lh_antennas.antenna[:].phase_average.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].phase_average.time"]
    lh_antennas.antenna[:].phase_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.definition

    Definition of the reference point

    • Data Type: STR_0D
    lh_antennas.antenna[:].position.phi.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.phi.time"]
    lh_antennas.antenna[:].position.phi.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.r.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.r.time"]
    lh_antennas.antenna[:].position.r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.z.time"]
    lh_antennas.antenna[:].position.z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_forward.time"]
    lh_antennas.antenna[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_launched.time"]
    lh_antennas.antenna[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_reflected.time"]
    lh_antennas.antenna[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].pressure_tank.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].pressure_tank.time"]
    lh_antennas.antenna[:].pressure_tank.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].reflection_coefficient.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].reflection_coefficient.time"]
    lh_antennas.antenna[:].reflection_coefficient.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].row[:].n_pol

    Refraction index in the poloidal direction. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/z

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].n_tor

    Refraction index in the toroidal direction

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].name

    Name of the row

    • Data Type: STR_0D
    lh_antennas.antenna[:].row[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].position.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].row[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].power_density_spectrum_1d

    1D power density spectrum dP/dn_tor, as a function of time

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["lh_antennas.antenna[:].row[:].n_tor", "lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].power_density_spectrum_2d

    2D power density spectrum d2P/(dntor.dnpol), as a function of time

    • Units: W
    • Data Type: FLT_3D
    • Coordinates: ["lh_antennas.antenna[:].row[:].n_tor", "lh_antennas.antenna[:].row[:].n_pol", "lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.code.library[:].name

    Name of software

    • Data Type: STR_0D
    lh_antennas.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    lh_antennas.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["lh_antennas.time"]
    lh_antennas.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.code.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    lh_antennas.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    lh_antennas.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    lh_antennas.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    lh_antennas.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    lh_antennas.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    lh_antennas.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    lh_antennas.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    lh_antennas.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    lh_antennas.power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.power_launched.time"]
    lh_antennas.power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.reference_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    lh_antennas.reference_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    lh_antennas.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].area

    Area of each turn of the sensor; becomes effective area when multiplied by the turns

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].bandwidth_3db

    3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_pol_probe[:].field.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].field.time"]
    magnetics.b_field_pol_probe[:].field.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].field.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].field.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].field.time"]
    magnetics.b_field_pol_probe[:].identifier

    ID of the probe

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].indices_differential

    Indices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_pol_probe[:].length

    Length of the sensor along it's normal vector (n)

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].name

    Name of the probe

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear

    Array of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linear

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].non_linear_response.b_field_non_linear

    Magnetic field value taking into account the non-linear response of the probe

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear"]
    magnetics.b_field_pol_probe[:].poloidal_angle

    Angle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].toroidal_angle

    Angle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].turns

    Turns in the coil, including sign

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].voltage.time"]
    magnetics.b_field_pol_probe[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].voltage.time"]
    magnetics.b_field_tor_probe[:].area

    Area of each turn of the sensor; becomes effective area when multiplied by the turns

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].bandwidth_3db

    3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_tor_probe[:].field.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].field.time"]
    magnetics.b_field_tor_probe[:].field.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].field.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].field.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].field.time"]
    magnetics.b_field_tor_probe[:].identifier

    ID of the probe

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].indices_differential

    Indices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_tor_probe[:].length

    Length of the sensor along it's normal vector (n)

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].name

    Name of the probe

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear

    Array of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linear

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].non_linear_response.b_field_non_linear

    Magnetic field value taking into account the non-linear response of the probe

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear"]
    magnetics.b_field_tor_probe[:].poloidal_angle

    Angle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].toroidal_angle

    Angle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].turns

    Turns in the coil, including sign

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].voltage.time"]
    magnetics.b_field_tor_probe[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].voltage.time"]
    magnetics.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.code.library[:].name

    Name of software

    • Data Type: STR_0D
    magnetics.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    magnetics.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["magnetics.time"]
    magnetics.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.code.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.diamagnetic_flux[:].data

    Data

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.diamagnetic_flux[:].time"]
    magnetics.diamagnetic_flux[:].method_name

    Name of the calculation method

    • Data Type: STR_0D
    magnetics.diamagnetic_flux[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].area

    Effective area (ratio between flux and average magnetic field over the loop)

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.flux_loop[:].flux.data

    Data

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.flux_loop[:].flux.time"]
    magnetics.flux_loop[:].flux.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].flux.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.flux_loop[:].flux.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.flux_loop[:].flux.time"]
    magnetics.flux_loop[:].gm9

    Integral of 1/R over the loop area (ratio between flux and magnetic rigidity R0.B0). Use only if ../type/index = 3 to 6, leave empty otherwise.

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].identifier

    ID of the flux loop

    • Data Type: STR_0D
    magnetics.flux_loop[:].indices_differential

    Indices (from the flux_loop array of structure) of the two flux loops used to build the flux difference flux(second index) - flux(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.flux_loop[:].name

    Name of the flux loop

    • Data Type: STR_0D
    magnetics.flux_loop[:].position[:].phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.flux_loop[:].position[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].position[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.flux_loop[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.flux_loop[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.flux_loop[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.flux_loop[:].voltage.time"]
    magnetics.flux_loop[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.flux_loop[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.flux_loop[:].voltage.time"]
    magnetics.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    magnetics.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    magnetics.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    magnetics.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    magnetics.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    magnetics.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    magnetics.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ip[:].data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.ip[:].time"]
    magnetics.ip[:].method_name

    Name of the calculation method

    • Data Type: STR_0D
    magnetics.ip[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].area

    Effective area of the loop wrapped around the guiding centre. In case of multiple layers, sum of the areas of each layer

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.rogowski_coil[:].current.time"]
    magnetics.rogowski_coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.rogowski_coil[:].current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.rogowski_coil[:].current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.rogowski_coil[:].current.time"]
    magnetics.rogowski_coil[:].identifier

    ID of the coil

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].indices_compound

    Indices (from the rogowskicoil array of structure) of the partial Rogoswkis used to build the coumpound signal (sum of the partial Rogoswki signals). Can be set to any unique integer value for each section of a compound rogowski coil. Use only if ../measurequantity/index = 5, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    magnetics.rogowski_coil[:].measured_quantity.description

    Verbose description

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].measured_quantity.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.rogowski_coil[:].measured_quantity.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].name

    Name of the coil

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].position[:].phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].position[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].position[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].turns_per_metre

    Number of turns per unit length. In case of multiple layers, turns are counted for a single layer

    • Units: m^-1
    • Data Type: FLT_0D
    magnetics.shunt[:].divertor_index

    If the shunt is located on a given divertor, index of that divertor in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].identifier

    Alphanumeric identifier of the shunt

    • Data Type: STR_0D
    magnetics.shunt[:].name

    Name of the shunt

    • Data Type: STR_0D
    magnetics.shunt[:].position.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].resistance

    Shunt resistance

    • Units: Ohm
    • Data Type: FLT_0D
    magnetics.shunt[:].target_index

    If the shunt is located on a divertor target, index of that target in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].tile_index

    If the shunt is located on a divertor tile, index of that tile in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.shunt[:].voltage.time"]
    magnetics.shunt[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.shunt[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.shunt[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.shunt[:].voltage.time"]
    magnetics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mhd.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mhd.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mhd.time"]
    mhd.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.code.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ggd[:].a_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_r[:].values", "1...N"]
    mhd.ggd[:].a_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].a_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_tor[:].values", "1...N"]
    mhd.ggd[:].a_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].a_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_z[:].values", "1...N"]
    mhd.ggd[:].a_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_r[:].values", "1...N"]
    mhd.ggd[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_tor[:].values", "1...N"]
    mhd.ggd[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_z[:].values", "1...N"]
    mhd.ggd[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].electrons.temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].electrons.temperature[:].values", "1...N"]
    mhd.ggd[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].electrons.temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_r[:].values", "1...N"]
    mhd.ggd[:].j_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_tor[:].values", "1...N"]
    mhd.ggd[:].j_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_tor_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_tor_r[:].values", "1...N"]
    mhd.ggd[:].j_tor_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_tor_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_tor_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_z[:].values", "1...N"]
    mhd.ggd[:].j_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].mass_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].mass_density[:].values", "1...N"]
    mhd.ggd[:].mass_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].mass_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].mass_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].n_i_total[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].n_i_total[:].values", "1...N"]
    mhd.ggd[:].n_i_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].n_i_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].n_i_total[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].phi_potential[:].values", "1...N"]
    mhd.ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].psi[:].values", "1...N"]
    mhd.ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].t_i_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].t_i_average[:].values", "1...N"]
    mhd.ggd[:].t_i_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].t_i_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].t_i_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd.ggd[:].velocity_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_parallel[:].values", "1...N"]
    mhd.ggd[:].velocity_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_parallel_over_b_field[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1.T^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_parallel_over_b_field[:].values", "1...N"]
    mhd.ggd[:].velocity_parallel_over_b_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel_over_b_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel_over_b_field[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1.T^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_r[:].values", "1...N"]
    mhd.ggd[:].velocity_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_tor[:].values", "1...N"]
    mhd.ggd[:].velocity_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_z[:].values", "1...N"]
    mhd.ggd[:].velocity_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].vorticity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].vorticity[:].values", "1...N"]
    mhd.ggd[:].vorticity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].vorticity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].vorticity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].vorticity_over_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].vorticity_over_r[:].values", "1...N"]
    mhd.ggd[:].vorticity_over_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].vorticity_over_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].vorticity_over_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].zeff[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].zeff[:].values", "1...N"]
    mhd.ggd[:].zeff[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].zeff[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].zeff[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element"]
    mhd.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element"]
    mhd.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mhd.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mhd.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mhd.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mhd.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mhd.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mhd.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mhd.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mhd.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mhd.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mhd.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mhd.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mhd.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mhd_linear.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mhd_linear.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mhd_linear.time"]
    mhd_linear.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.code.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.equations.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.equations.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.equations.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.fluids_n

    Number of fluids considered in the model

    • Data Type: INT_0D
    mhd_linear.ideal_flag

    1 if ideal MHD is used to populate this IDS, 0 for non-ideal MHD

    • Data Type: INT_0D
    mhd_linear.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mhd_linear.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mhd_linear.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mhd_linear.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mhd_linear.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mhd_linear.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mhd_linear.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.model_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.model_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.model_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].amplitude_multiplier

    Multiplier that is needed to convert the linear mode structures to the amplitude of a non-linearly saturated mode in physical units. If empty, it means that the structures contains no information about non-linearly saturated mode

    • Units: mixed
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].energy_perturbed

    Perturbed energy associated to the mode

    • Units: J
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].growthrate

    Linear growthrate of the mode

    • Units: Hz
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].m_pol_dominant

    Dominant poloidal mode number defining the mode rational surface; for TAEs the lower of the two main m's has to be specified

    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].n_tor

    Toroidal mode number of the MHD mode

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].phase

    Additional phase offset of mode

    • Units: rad
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].imaginary

    Imaginary part of the frequency, for a given radial position and every root found at this position

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real

    Real part of the frequency, for a given radial position and every root found at this position

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.imaginary

    Imaginary part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.real

    Real part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.imaginary

    Imaginary part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.real

    Real part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: kg.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: kg.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.imaginary

    Imaginary part

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.real

    Real part

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.imaginary

    Imaginary part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.real

    Real part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: Pa
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: Pa
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.imaginary

    Imaginary part

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.real

    Real part

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.imaginary

    Imaginary part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.real

    Real part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_alfven

    Alven time=R/vA=R0 sqrt(mi ni(rho))/B0

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_resistive

    Resistive time = mu0 rho*rho/1.22/etaneo

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: eV
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: eV
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.imaginary

    Imaginary part

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.real

    Real part

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].radial_mode_number

    Radial mode number

    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time"]
    mhd_linear.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].geometric_coefficients

    Set of 9 geometric coefficients providing the MSE polarisation angle as a function of the local electric and magnetic field components (these are related to the angle between beam and line of sight). The list is ordered as follows : coefficients of BZ, BR, Bphi, ER (numerator of the MSE angle expression); coefficients of BZ, BR, Bphi, ER, EZ (denominator)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...9"]
    mse.channel[:].active_spatial_resolution[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    mse.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].aperture[:].outline.x1"]
    mse.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    mse.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].detector.outline.x1"]
    mse.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    mse.channel[:].polarisation_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].polarisation_angle.time"]
    mse.channel[:].polarisation_angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].polarisation_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    mse.channel[:].polarisation_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["mse.channel[:].polarisation_angle.time"]
    mse.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mse.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mse.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mse.time"]
    mse.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.code.repository

    URL of software repository

    • Data Type: STR_0D
    mse.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mse.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mse.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mse.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mse.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mse.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mse.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mse.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mse.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mse.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mse.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mse.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mse.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mse.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    mse.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.code.library[:].name

    Name of software

    • Data Type: STR_0D
    nbi.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    nbi.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["nbi.time"]
    nbi.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.code.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    nbi.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    nbi.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    nbi.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    nbi.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    nbi.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    nbi.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    nbi.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    nbi.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    nbi.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    nbi.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    nbi.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    nbi.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    nbi.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    nbi.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    nbi.unit[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].aperture[:].outline.x1"]
    nbi.unit[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    nbi.unit[:].beam_current_fraction.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "nbi.unit[:].beam_current_fraction.time"]
    nbi.unit[:].beam_current_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beam_power_fraction.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "nbi.unit[:].beam_power_fraction.time"]
    nbi.unit[:].beam_power_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beamlets_group[:].angle

    Angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal plane

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].beamlets.angles

    Angle of inclination between a line at the centre of a beamlet and the horizontal plane, for each beamlet

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.power_fractions

    Fraction of power of a unit injected by each beamlet

    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.tangency_radii

    Tangency radius (major radius where the central line of a beamlet is tangent to a circle around the torus), for each beamlet

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].direction

    Direction of the beam seen from above the torus: -1 = clockwise; 1 = counter clockwise

    • Data Type: INT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].horizontal

    The horiztonal beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].particles_fraction

    Fraction of injected particles in the component

    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].vertical

    The vertical beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.focal_length_horizontal

    Horizontal focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum horizontal width

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.focal_length_vertical

    Vertical focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum vertical width

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.width_min_horizontal

    The horizontal width (Full Width at Half Maximum) of the beamlets group at the horizontal focal point

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.width_min_vertical

    The vertical width (Full Width at Half Maximum) of the beamlets group at the vertical focal point

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tangency_radius

    Tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_angle

    Variation of the angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal plane

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_tangency_radius

    Variation of the tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].width_horizontal

    Horizontal width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].width_vertical

    Vertical width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].efficiency.conversion

    Conversion efficiency of electric power to neutral beam power

    • Data Type: FLT_0D
    nbi.unit[:].efficiency.transmission

    Transmission efficiency of neutral beam from source to port

    • Data Type: FLT_0D
    nbi.unit[:].energy.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].energy.time"]
    nbi.unit[:].energy.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].identifier

    ID of the NBI unit

    • Data Type: STR_0D
    nbi.unit[:].name

    Name of the NBI unit

    • Data Type: STR_0D
    nbi.unit[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].power_launched.time"]
    nbi.unit[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].source.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].source.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    nbi.unit[:].source.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].source.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].source.outline.x1"]
    nbi.unit[:].source.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].species.a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    nbi.unit[:].species.label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    nbi.unit[:].species.z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    neutron_diagnostic.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].name

    Name of software

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    neutron_diagnostic.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.code.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].adc.bias

    ADC signal bias

    • Units: V
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.discriminator_level_lower

    Lower level discriminator of ADC

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.discriminator_level_upper

    Upper level discriminator of ADC

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.impedance

    ADC impedance

    • Units: ohm
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.input_range

    ADC input range

    • Units: V
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.sampling_rate

    Number of samples recorded per second

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].aperture[:].outline.x1"]
    neutron_diagnostic.detector[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].b_field_sensor.amplitude.time"]
    neutron_diagnostic.detector[:].b_field_sensor.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].b_field_sensor.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].b_field_sensor.frequency.time"]
    neutron_diagnostic.detector[:].b_field_sensor.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].b_field_sensor.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].b_field_sensor.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].energy_band[:].energies"]
    neutron_diagnostic.detector[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.x

    Components along X axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.y

    Component along Y axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.z

    Component along Z axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.solid_angle

    Average solid angle that the detector covers within the voxel

    • Units: sr
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].geometry.outline.x1"]
    neutron_diagnostic.detector[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values

    Array of values for the event

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values

    Array of values for the event

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].green_functions.neutron_flux

    Grouped neutron flux in the detector from one neutron energy bin emitted by the current plasma voxel towards the detector

    • Units: m^-2.neutron^-1
    • Data Type: FLT_5D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi", "neutron_diagnostic.detector[:].green_functions.source_neutron_energies", "neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values"]
    neutron_diagnostic.detector[:].green_functions.neutron_flux_integrated_flags

    Array of flags telling, for each coordinate of the neutronflux, whether the neutronflux has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1

    • Data Type: INT_1D
    • Coordinates: ["1...5"]
    neutron_diagnostic.detector[:].green_functions.response_function

    Number of events occurring in the detector from one neutron energy bin emitted by the current plasma voxel towards the detector

    • Units: events.neutron^-1
    • Data Type: FLT_5D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi", "neutron_diagnostic.detector[:].green_functions.source_neutron_energies", "neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values"]
    neutron_diagnostic.detector[:].green_functions.response_function_integrated_flags

    Array of flags telling, for each coordinate of the responsefunction, whether the responsefunction has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1

    • Data Type: INT_1D
    • Coordinates: ["1...5"]
    neutron_diagnostic.detector[:].green_functions.source_neutron_energies

    Array of source neutron energy bins

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].material.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].material.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].count_limit_max

    Maximum count limit under which the detector response is linear

    • Units: counts.s^-1
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].mode[:].count_limit_min

    Minimum count limit above which the detector response is linear

    • Units: counts.s^-1
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].mode[:].counting.data

    Data

    • Units: counts.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].mode[:].counting.time"]
    neutron_diagnostic.detector[:].mode[:].counting.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].mode[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].mode[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].spectrum.data

    Data

    • Units: counts.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "neutron_diagnostic.detector[:].mode[:].spectrum.time"]
    neutron_diagnostic.detector[:].mode[:].spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].name

    Name of the detector

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].nuclei_n

    Number of target nuclei in the dectector

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_high_voltage.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_low_voltage.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature

    Temperature of the detector

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.detector[:].temperature_sensor.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].temperature_sensor.amplitude.time"]
    neutron_diagnostic.detector[:].temperature_sensor.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature_sensor.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].temperature_sensor.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].temperature_sensor.frequency.time"]
    neutron_diagnostic.detector[:].temperature_sensor.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature_sensor.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].temperature_sensor.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].test_generator.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].test_generator.amplitude.time"]
    neutron_diagnostic.detector[:].test_generator.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].test_generator.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].test_generator.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].test_generator.frequency.time"]
    neutron_diagnostic.detector[:].test_generator.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].test_generator.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].test_generator.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].test_generator.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].test_generator.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].test_generator.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.fusion_power

    Fusion power reconstructed from the detectors signals

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.neutron_flux_total

    Total Neutron Flux reconstructed from the detectors signals

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.first_wall.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.first_wall.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    neutronics.time_slice[:].wall_loading.flux_r

    Average radial component of the neutron flux

    • Units: W/m^2
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time_slice[:].wall_loading.flux_z

    Average vertical component of the neutron flux

    • Units: W/m^2
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time_slice[:].wall_loading.power

    Local neutron power (ie. integrated neutron flux)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    ntms.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ntms.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ntms.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ntms.time"]
    ntms.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.code.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ntms.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ntms.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ntms.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ntms.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ntms.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ntms.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ntms.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ntms.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ntms.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ntms.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ntms.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ntms.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ntms.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ntms.time_slice[:].mode[:].calculation_method

    Description of how the mode evolution is calculated

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].delta_diff

    Extra diffusion coefficient for the transport equations of Te, ne, Ti

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    ntms.time_slice[:].mode[:].deltaw[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].deltaw[:].value

    Value of the contribution

    • Units: m^-1
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.calculation_method

    Description of how the mode evolution is calculated

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.delta_diff

    Extra diffusion coefficient for the transport equations of Te, ne, Ti

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].value

    Value of the contribution

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dfrequency_dt

    Time derivative of the frequency of the mode

    • Units: s^-2
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dphase_dt

    Time derivative of the phase of the mode

    • Units: rad/s
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dwidth_dt

    Time derivative of the full width of the mode

    • Units: m/s
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.phase

    Phase of the mode

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.rho_tor

    Flux coordinate on which the mode is centred

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.rho_tor_norm

    Normalised flux coordinate on which the mode is centred

    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.time_detailed

    Time array used to describe the detailed evolution of the NTM

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ntms.time_slice[:].mode[:].detailed_evolution.torque[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.torque[:].value

    Value of the contribution

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.width

    Full width of the mode

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].dfrequency_dt

    Time derivative of the frequency of the mode

    • Units: s^-2
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].dphase_dt

    Time derivative of the phase of the mode

    • Units: rad/s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].dwidth_dt

    Time derivative of the full width of the mode

    • Units: m/s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.cause

    Cause of the mode onset

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].onset.m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.phase

    Phase of the mode at onset

    • Units: rad
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.time_offset

    Offset time (when a mode disappears). If the mode reappears later in the simulation, use another index of the mode array of structure

    • Units: s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.time_onset

    Onset time

    • Units: s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.width

    Seed island full width at onset time

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].phase

    Phase of the mode

    • Units: rad
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].rho_tor

    Flux coordinate on which the mode is centred

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].rho_tor_norm

    Normalised flux coordinate on which the mode is centred

    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].torque[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].torque[:].value

    Value of the contribution

    • Units: kg.m^2.s^-2
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].width

    Full width of the mode

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ntms.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time"]
    ntms.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    operational_instrumentation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["operational_instrumentation.time"]
    operational_instrumentation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.code.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].acceleration.data

    Data

    • Units: m.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].acceleration.time"]
    operational_instrumentation.sensor[:].acceleration.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].attachement_points[:].x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_points[:].y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_points[:].z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_uris

    IMAS URI of the system(s) to which this sensor is attached. Two for displacement sensors, one for the other types of sensors

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].gauge_length

    Length of the strain gauge

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].identifier

    ID of the sensor

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].length.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].length.time"]
    operational_instrumentation.sensor[:].length.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].name

    Name of the sensor

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].strain.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].strain.time"]
    operational_instrumentation.sensor[:].strain.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].strain_rosette.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "operational_instrumentation.sensor[:].strain_rosette.time"]
    operational_instrumentation.sensor[:].strain_rosette.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].temperature.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].temperature.time"]
    operational_instrumentation.sensor[:].temperature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].type.description

    Verbose description

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    operational_instrumentation.sensor[:].type.name

    Short string identifier

    • Data Type: STR_0D
    operational_instrumentation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pellets.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pellets.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pellets.time"]
    pellets.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.code.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pellets.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pellets.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pellets.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pellets.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pellets.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pellets.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pellets.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pellets.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pellets.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pellets.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pellets.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pellets.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    pellets.launcher[:].name

    Name of the launcher (unique within the set of all launchers of the experiment)

    • Data Type: STR_0D
    pellets.launcher[:].shape.size

    Size of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the length

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.launcher[:].shape.type.description

    Verbose description

    • Data Type: STR_0D
    pellets.launcher[:].shape.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.launcher[:].shape.type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.launcher[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.launcher[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.launcher[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].frequency

    Frequency of pellets launched

    • Units: Hz
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].density

    Material density of the species in the pellet

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].fraction

    Atomic fraction of the species in the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].sublimation_energy

    Sublimation energy per atom

    • Units: eV
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].thickness

    Layer thickness

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_profiles.ablated_particles

    Number of ablated particles (electrons) along the pellet path

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.ablation_rate

    Ablation rate (electrons) along the pellet path

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.distance

    Distance along the pellet path, with the origin taken at pathgeometry/firstpoint. Used as the main coordinate for the path_profiles structure

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].path_profiles.n_e

    Electron density along the pellet path

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.position.r"]
    pellets.time_slice[:].pellet[:].path_profiles.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].path_profiles.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.position.r"]
    pellets.time_slice[:].pellet[:].path_profiles.psi

    Poloidal flux along the pellet path

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm

    Normalised toroidal coordinate along the pellet path

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm_drift

    Difference to due ExB drifts between the ablation and the final deposition locations, in terms of the normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.t_e

    Electron temperature along the pellet path

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.velocity

    Pellet velocity along the pellet path

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.label

    String identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].propellant_gas.molecules_n

    Number of molecules of the propellant gas injected in the vacuum vessel when launching the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].shape.size

    Size of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the length

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].shape.type.description

    Verbose description

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].shape.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.time_slice[:].pellet[:].shape.type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].density

    Material density of the species in the pellet

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].fraction

    Atomic fraction of the species in the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].species[:].sublimation_energy

    Sublimation energy per atom

    • Units: eV
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].velocity_initial

    Initial velocity of the pellet as it enters the vaccum chamber

    • Units: m.s^-1
    • Data Type: FLT_0D
    pellets.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    pf_active.circuit[:].connections

    Description of the supplies and coils connections (nodes) across the circuit. Nodes of the circuit are listed as the first dimension of the matrix. Supplies (listed first) and coils (listed second) SIDES are listed as the second dimension. Thus the second dimension has a size equal to 2*(Nsupplies+Ncoils). Nsupplies (resp. Ncoils) is the total number of supplies (resp. coils) listed in the supply (resp.coil) array of structure, i.e. including also supplies/coils that are not part of the actual circuit. The (i,j) matrix elements are 1 if the j-th supply or coil side is connected to the i-th node, or 0 otherwise. For coils, sides are listed so that a current flowing from side 1 to side 2 (inside the coil) is positive (i.e. counter-clockwise when seen from above).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    pf_active.circuit[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.circuit[:].current.time"]
    pf_active.circuit[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.circuit[:].identifier

    ID of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].name

    Name of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].type

    Type of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.circuit[:].voltage.time"]
    pf_active.circuit[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_active.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_active.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_active.time"]
    pf_active.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.coil[:].b_field_max

    List of values of the maximum magnetic field on the conductor surface (coordinate for currentlimitmax)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].b_field_max_timed.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].b_field_max_timed.time"]
    pf_active.coil[:].b_field_max_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].current.time"]
    pf_active.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].current_limit_max

    Maximum tolerable current in the conductor

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["pf_active.coil[:].b_field_max", "pf_active.coil[:].temperature"]
    pf_active.coil[:].element[:].area

    Cross-sectional areas of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.arcs_of_circle.r"]
    pf_active.coil[:].element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.arcs_of_circle.r"]
    pf_active.coil[:].element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_active.coil[:].element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.outline.r"]
    pf_active.coil[:].element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].identifier

    Identifier of this element

    • Data Type: STR_0D
    pf_active.coil[:].element[:].name

    Name of this element

    • Data Type: STR_0D
    pf_active.coil[:].element[:].turns_with_sign

    Number of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)

    • Data Type: FLT_0D
    pf_active.coil[:].energy_limit_max

    Maximum Energy to be dissipated in the coil

    • Units: J
    • Data Type: FLT_0D
    pf_active.coil[:].force_radial.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_radial.time"]
    pf_active.coil[:].force_radial.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_radial_crushing.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_radial_crushing.time"]
    pf_active.coil[:].force_radial_crushing.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_vertical.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_vertical.time"]
    pf_active.coil[:].force_vertical.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_vertical_crushing.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_vertical_crushing.time"]
    pf_active.coil[:].force_vertical_crushing.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].function[:].description

    Verbose description

    • Data Type: STR_0D
    pf_active.coil[:].function[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_active.coil[:].function[:].name

    Short string identifier

    • Data Type: STR_0D
    pf_active.coil[:].identifier

    Alphanumeric identifier of coils used for convenience

    • Data Type: STR_0D
    pf_active.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    pf_active.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_active.coil[:].resistance_additional.data

    Data

    • Units: Ohm
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].resistance_additional.time"]
    pf_active.coil[:].resistance_additional.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].temperature

    List of values of the conductor temperature (coordinate for currentlimitmax)

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].voltage.time"]
    pf_active.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.combination_matrix

    Force limits are expressed as a linear combination of the forces on each individual coil. The weights of the linear combination are given by this matrix, while the limits are given by the sibling nodes limitmin and limitmax. Each row of this matrix corresponds to a force limit. The columns represent, for each coil, the 4 types of forces on the coil namely [coil1radial, coil1vertical, coil1radialcrush, coil1verticalcrush, coil2radial, coil2vertical, coil2radialcrush, coil2verticalcrush, ...]. There are therefore 4*coils_n columns.

    • Data Type: FLT_2D
    • Coordinates: ["pf_active.force_limits.limit_max", "1...N"]
    pf_active.force_limits.force.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.force_limits.force.time"]
    pf_active.force_limits.force.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.limit_max

    Maximum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unbounded

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.limit_min

    Minimum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unbounded

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.force_limits.limit_max"]
    pf_active.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_active.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_active.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_active.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_active.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_active.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_active.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_active.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_active.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_active.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    pf_active.supply[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.supply[:].current.time"]
    pf_active.supply[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].current_limit_max

    Maximum current in the supply

    • Units: A
    • Data Type: FLT_0D
    pf_active.supply[:].current_limit_min

    Minimum current in the supply

    • Units: A
    • Data Type: FLT_0D
    pf_active.supply[:].current_limiter_gain

    Gain to prevent overcurrent in a linear model of the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.supply[:].delay

    Pure delay in the supply

    • Units: s
    • Data Type: FLT_0D
    pf_active.supply[:].energy_limit_max

    Maximum energy to be dissipated in the supply during a pulse

    • Units: J
    • Data Type: FLT_0D
    pf_active.supply[:].filter_denominator

    Coefficients of the denominator, in increasing order : b0 + b1s + ... + bms^m; used for a linear supply description

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].filter_numerator

    Coefficients of the numerator, in increasing order : a0 + a1s + ... + ans^n; used for a linear supply description

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].identifier

    Identifier of the supply

    • Data Type: STR_0D
    pf_active.supply[:].name

    Name of the PF supply

    • Data Type: STR_0D
    pf_active.supply[:].nonlinear_model

    Description of the nonlinear transfer function of the supply

    • Data Type: STR_0D
    pf_active.supply[:].resistance

    Power supply internal resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_active.supply[:].type

    Type of the supply; TBD add free description of non-linear power supplies

    • Data Type: INT_0D
    pf_active.supply[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.supply[:].voltage.time"]
    pf_active.supply[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].voltage_limit_max

    Maximum voltage from the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.supply[:].voltage_limit_min

    Minimum voltage from the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_passive.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_passive.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_passive.time"]
    pf_passive.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_passive.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_passive.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_passive.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_passive.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_passive.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_passive.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_passive.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_passive.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.loop[:].current

    Passive loop current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].time"]
    pf_passive.loop[:].element[:].area

    Cross-sectional areas of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.arcs_of_circle.r"]
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.arcs_of_circle.r"]
    pf_passive.loop[:].element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_passive.loop[:].element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.loop[:].element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.outline.r"]
    pf_passive.loop[:].element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].identifier

    Identifier of this element

    • Data Type: STR_0D
    pf_passive.loop[:].element[:].name

    Name of this element

    • Data Type: STR_0D
    pf_passive.loop[:].element[:].turns_with_sign

    Number of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)

    • Data Type: FLT_0D
    pf_passive.loop[:].name

    Name of the loop

    • Data Type: STR_0D
    pf_passive.loop[:].resistance

    Passive loop resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_passive.loop[:].resistivity

    Passive loop resistivity

    • Units: Ohm.m
    • Data Type: FLT_0D
    pf_passive.loop[:].time

    Timebase for the dynamic nodes of this loop located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_plasma.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_plasma.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_plasma.time"]
    pf_plasma.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.element[:].area

    Cross-sectional area of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_plasma.element[:].current

    Current in the plasma element

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].time"]
    pf_plasma.element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.arcs_of_circle.r"]
    pf_plasma.element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.arcs_of_circle.r"]
    pf_plasma.element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_plasma.element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.outline.r"]
    pf_plasma.element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].time

    Timebase for the dynamic nodes located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_plasma.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_plasma.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_plasma.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_plasma.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_plasma.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_plasma.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_plasma.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_plasma.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].e_field_parallel

    Parallel electric field along each field line

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].e_field_townsend

    Townsend electric field along each field line

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.b_field_lines[:].grid.dim1", "plasma_initiation.b_field_lines[:].grid.dim2"]
    plasma_initiation.b_field_lines[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.b_field_lines[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.b_field_lines[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.b_field_lines[:].lengths

    Length of each field line

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].open_fraction

    Fraction of open field lines : ratio open fields lines / (open+closed field lines)

    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].pressure

    Prefill gas pressure used in Townsend E field calculation

    • Units: Pa
    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].starting_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].starting_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r"]
    plasma_initiation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    plasma_initiation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    plasma_initiation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["plasma_initiation.time"]
    plasma_initiation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.code.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.global_quantities.b_field_perpendicular.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.b_field_perpendicular.time"]
    plasma_initiation.global_quantities.b_field_perpendicular.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.b_field_stray.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.b_field_stray.time"]
    plasma_initiation.global_quantities.b_field_stray.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.connection_length.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.connection_length.time"]
    plasma_initiation.global_quantities.connection_length.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.coulomb_logarithm.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.coulomb_logarithm.time"]
    plasma_initiation.global_quantities.coulomb_logarithm.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    plasma_initiation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    plasma_initiation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    plasma_initiation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    plasma_initiation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    plasma_initiation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    plasma_initiation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].e_field_tor

    Toroidal component of the electric field

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.profiles_2d[:].grid.dim1", "plasma_initiation.profiles_2d[:].grid.dim2"]
    plasma_initiation.profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.profiles_2d[:].grid.dim1", "plasma_initiation.profiles_2d[:].grid.dim2"]
    plasma_initiation.profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    plasma_initiation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].ellipticity.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["polarimeter.channel[:].ellipticity.time"]
    polarimeter.channel[:].ellipticity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].ellipticity.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    polarimeter.channel[:].ellipticity.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.channel[:].ellipticity.time"]
    polarimeter.channel[:].ellipticity_initial

    Initial ellipticity before entering the plasma

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].faraday_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["polarimeter.channel[:].faraday_angle.time"]
    polarimeter.channel[:].faraday_angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].faraday_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    polarimeter.channel[:].faraday_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.channel[:].faraday_angle.time"]
    polarimeter.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    polarimeter.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    polarimeter.channel[:].polarisation_initial

    Initial polarisation vector before entering the plasma

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].wavelength

    Wavelength used for polarimetry

    • Units: m
    • Data Type: FLT_0D
    polarimeter.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.code.library[:].name

    Name of software

    • Data Type: STR_0D
    polarimeter.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    polarimeter.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.time"]
    polarimeter.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.code.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    polarimeter.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    polarimeter.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    polarimeter.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    polarimeter.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    polarimeter.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    polarimeter.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    polarimeter.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    polarimeter.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    polarimeter.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pulse_schedule.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pulse_schedule.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.time"]
    pulse_schedule.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.code.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].z_ion

    Ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_greenwald_fraction.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_line.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_lcfs.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_lcfs.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line_lcfs.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_line_lcfs.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_pedestal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_pedestal_greenwald_fraction.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_profile_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_profile_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_profile_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_profile_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_volume_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_volume_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_volume_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_volume_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_h_over_n_d.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_h_over_n_d.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_h_over_n_d.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_h_over_n_d.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_t_over_n_d.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_t_over_n_d.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_t_over_n_d.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_t_over_n_d.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.density_control.valve[:].flow_rate.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].flow_rate.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.valve[:].flow_rate.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].flow_rate.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].identifier

    Identifier of the valve

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].name

    Name of the valve

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.zeff.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_method.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff_method.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff_pedestal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].identifier

    Identifier of the beam

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].name

    Name of the beam

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].power_launched.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].power_launched.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].power_launched.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].power_launched.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].steering_angle_pol.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].steering_angle_tor.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.power_launched.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.power_launched.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.power_launched.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.power_launched.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.event[:].acquisition_state.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_state.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].acquisition_state.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_strategy.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_strategy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].acquisition_strategy.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.event[:].duration

    Duration of this event

    • Units: s
    • Data Type: FLT_0D
    pulse_schedule.event[:].identifier

    Unique identifier of this event provided by the scheduling / event handler

    • Data Type: STR_0D
    pulse_schedule.event[:].listeners

    Systems listening to this event

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pulse_schedule.event[:].provider

    System having generated this event

    • Data Type: STR_0D
    pulse_schedule.event[:].time_stamp

    Time stamp of this event

    • Units: s
    • Data Type: FLT_0D
    pulse_schedule.event[:].type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.flux_control.beta_normal.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.beta_normal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.beta_normal.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.beta_normal.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.i_plasma.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.i_plasma.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.i_plasma.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.i_plasma.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.li_3.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.li_3.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.li_3.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.li_3.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.loop_voltage.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.loop_voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.loop_voltage.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.loop_voltage.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ic.antenna[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].identifier

    Identifier of the antenna

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].name

    Name of the antenna

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].phase.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].phase.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].phase.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].phase.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].power_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.ic.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pulse_schedule.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pulse_schedule.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pulse_schedule.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pulse_schedule.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pulse_schedule.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].identifier

    Identifier of the antenna

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].n_parallel.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].n_parallel.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].n_parallel.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].n_parallel.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].name

    Name of the antenna

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].phase.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].phase.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].phase.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].phase.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].power_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.lh.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.nbi.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.nbi.unit[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].energy.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].energy.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].energy.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].energy.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].identifier

    Identifier of the NBI unit

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].name

    Name of the NBI unit

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.launcher[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.pf_active.coil[:].current.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].current.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.coil[:].current.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].current.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].identifier

    Identifier of the coil

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.coil[:].resistance_additional.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].current.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].current.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].current.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].current.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].identifier

    Identifier of the supply

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].name

    Name of the supply

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].voltage.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].voltage.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].voltage.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.position_control.active_limiter_point.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.active_limiter_point.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.active_limiter_point.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.active_limiter_point.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.active_limiter_point.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.boundary_outline[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.boundary_outline[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.boundary_outline[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.boundary_outline[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.current_centroid.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.current_centroid.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.current_centroid.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.current_centroid.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_lower.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_lower.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation_lower.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation_lower.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_upper.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_upper.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation_upper.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation_upper.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].angle

    Angle between the direction in which the gap is measured (in the poloidal cross-section) and the horizontal axis.

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.position_control.gap[:].identifier

    Identifier of the gap

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].name

    Name of the gap

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].r

    Major radius of the reference point

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.position_control.gap[:].value.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].value.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.gap[:].value.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].value.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].z

    Height of the reference point

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.position_control.geometric_axis.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.geometric_axis.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.geometric_axis.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.geometric_axis.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.geometric_axis.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.magnetic_axis.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.magnetic_axis.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.magnetic_axis.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.magnetic_axis.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.minor_radius.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.minor_radius.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.minor_radius.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.minor_radius.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.ovality.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_lower_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_lower_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_upper_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_upper_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_upper_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_upper_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.strike_point[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.strike_point[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.strike_point[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.strike_point[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.tilt.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.position_control.triangularity.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_lower.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_lower.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_lower.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_lower.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_minor.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_minor.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_minor.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_minor.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_upper.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_upper.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_upper.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_upper.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.twist.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.x_point[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.x_point[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_max.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_max.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.z_r_max.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.z_r_max.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_min.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_min.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.z_r_min.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.z_r_min.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.profiles_control.dpressure_dpsi.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: Pa.Wb^-1
    • Data Type: FLT_2D
    • Coordinates: ["pulse_schedule.profiles_control.psi_norm", "pulse_schedule.profiles_control.time"]
    pulse_schedule.profiles_control.f_df_dpsi.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["pulse_schedule.profiles_control.psi_norm", "pulse_schedule.profiles_control.time"]
    pulse_schedule.profiles_control.psi_norm

    Radial dimension

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.profiles_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.tf.b_field_tor_vacuum.reference

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.b_field_tor_vacuum_r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.tf.b_field_tor_vacuum_r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.b_field_tor_vacuum_r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.tf.b_field_tor_vacuum_r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.tf.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.tf.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    radiation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    radiation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["radiation.time"]
    radiation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.code.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element"]
    radiation.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element"]
    radiation.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    radiation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    radiation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    radiation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    radiation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    radiation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    radiation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    radiation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    radiation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    radiation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    radiation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].electrons.emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].electrons.emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].ion[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].ion[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].neutral[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power

    Total power emitted by all species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_electrons

    Power emitted by electrons

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_ion_total

    Total power emitted by all ion species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_neutral_total

    Total power emitted by all neutral species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power

    Total power emitted by all species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_electrons

    Power emitted by electrons

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_ion_total

    Total power emitted by all ion species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_neutral_total

    Total power emitted by all neutral species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.process[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].electrons.emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].electrons.power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].emissivity_ion_total

    Emissivity (summed over ion species)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].emissivity_neutral_total

    Emissivity (summed over neutral species)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].power_inside_ion_total

    Total power from ion species (summed over ion species) inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].power_inside_neutral_total

    Total power from ion species (summed over neutral species) inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["radiation.time"]
    radiation.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    real_time_data.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.code.library[:].name

    Name of software

    • Data Type: STR_0D
    real_time_data.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    real_time_data.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.time"]
    real_time_data.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.code.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    real_time_data.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    real_time_data.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    real_time_data.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    real_time_data.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    real_time_data.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    real_time_data.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    real_time_data.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    real_time_data.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    real_time_data.topic[:].name

    Topic name

    • Data Type: STR_0D
    real_time_data.topic[:].sample

    Index of sample (time stamp counter)

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].signal[:].allocated_position

    Allocation of signal to a position in the SDN (1..N), or several positions in case of signal reshaping; this will be implementation specific

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    real_time_data.topic[:].signal[:].data_str

    Signal data (e.g. diagnostic signal or PCS command), serialized as a string

    • Data Type: STR_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].signal[:].data_type

    Signal data type

    • Data Type: STR_0D
    real_time_data.topic[:].signal[:].name

    Signal name

    • Data Type: STR_0D
    real_time_data.topic[:].signal[:].quality

    Indicator of the quality of the signal. Following ITER PCS documentation (https://user.iter.org/?uid=354SJ3&action=get_document), possible values are: 1 - GOOD (the nominal state); 2 - INVALID (data no usable); 3 - DATA INTEGRITY ERROR (e.g. out of bounds with respect to expectations, calibration error,...)

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].time_stamp

    Time of creation for all signals belonging to this topic. A set of time stamps can be recorded if needed

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].amplitude.time"]
    reflectometer_fluctuation.channel[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1"]
    reflectometer_fluctuation.channel[:].antenna_emission_static.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.e_field_radial

    Radial electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.radial_width

    Width in the radial direction over which fluctuating profiles are processed

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.shift

    Doppler frequency shift (for the main peak of the power spectrum)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].doppler.time_width

    Width of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.wavenumber

    Wavenumber probed by the diagnostic

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.dn_e_over_n_e

    Relative amplitude of the density fluctuations post-processed for swept and fixed frequency (profile/one point)

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.radial_width

    Width in the radial direction over which fluctuating profiles are processed

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].fluctuations_level.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_level.time_width

    Width of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier

    Array of frequencies used for the Fourier transform

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.power_log

    Power spectrum in log scale

    • Units: dB
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier", "reflectometer_fluctuation.channel[:].fluctuations_spectrum.time"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.time_width

    Width of the time interval over which the spectrum is processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].frequencies.data

    Data

    • Units: Hz
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].frequencies.time"]
    reflectometer_fluctuation.channel[:].frequencies.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].phase.time"]
    reflectometer_fluctuation.channel[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].raw_signal.i_component

    I component of the IQ detector used to retrieve the phase of signal's envelope

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].raw_signal.time"]
    reflectometer_fluctuation.channel[:].raw_signal.q_component

    Q component of the IQ detector used to retrieve the phase of signal's envelope

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].raw_signal.time"]
    reflectometer_fluctuation.channel[:].raw_signal.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].sweep_time

    Duration of a sweep

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["reflectometer_fluctuation.time"]
    reflectometer_fluctuation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.code.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.psi_normalization.time"]
    reflectometer_fluctuation.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.psi_normalization.time"]
    reflectometer_fluctuation.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.type

    Type of reflectometer (frequency_swept, radar, ...)

    • Data Type: STR_0D
    reflectometer_profile.channel[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].amplitude.time"]
    reflectometer_profile.channel[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_detection.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_profile.channel[:].antenna_detection.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_detection.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.channel[:].antenna_detection.outline.x1"]
    reflectometer_profile.channel[:].antenna_detection.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_profile.channel[:].antenna_emission.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_emission.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.channel[:].antenna_emission.outline.x1"]
    reflectometer_profile.channel[:].antenna_emission.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].cut_off_frequency

    Cut-off frequency as a function of measurement position and time

    • Units: Hz
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].frequencies

    Array of frequencies scanned during a sweep

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    reflectometer_profile.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    reflectometer_profile.channel[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].phase.time"]
    reflectometer_profile.channel[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].sweep_time

    Duration of a sweep

    • Units: s
    • Data Type: FLT_0D
    reflectometer_profile.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].name

    Name of software

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    reflectometer_profile.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["reflectometer_profile.time"]
    reflectometer_profile.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.code.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_profile.n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.psi_normalization.time"]
    reflectometer_profile.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.psi_normalization.time"]
    reflectometer_profile.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.type

    Type of reflectometer (frequency_swept, radar, ...)

    • Data Type: STR_0D
    refractometer.channel[:].bandwidth[:].frequency_main

    Main frequency used to probe the plasma (before upshifting and modulating)

    • Units: Hz
    • Data Type: FLT_0D
    refractometer.channel[:].bandwidth[:].i_component

    I component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vector

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].bandwidth[:].n_e_line.time"]
    refractometer.channel[:].bandwidth[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].phase

    Phase of the envelope of the probing signal, relative to the phase at launch

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].phase_quadrature.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].phase_quadrature.time"]
    refractometer.channel[:].bandwidth[:].phase_quadrature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].q_component

    Q component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vector

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].time

    Timebase for this bandwidth

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].time_detector

    High sampling timebase of the IQ-detector signal measurements

    • Units: s
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    refractometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    refractometer.channel[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].n_e_line.time"]
    refractometer.channel[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].n_e_profile_approximation.formula.description

    Verbose description

    • Data Type: STR_0D
    refractometer.channel[:].n_e_profile_approximation.formula.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    refractometer.channel[:].n_e_profile_approximation.formula.name

    Short string identifier

    • Data Type: STR_0D
    refractometer.channel[:].n_e_profile_approximation.parameters

    Values of the formula's parameters alpha1, ..., alphaN

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].n_e_line.time"]
    refractometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    refractometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    refractometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    refractometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["refractometer.time"]
    refractometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    refractometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    refractometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    refractometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    refractometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    refractometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    refractometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    refractometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    refractometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    refractometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    refractometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.type

    Type of refractometer (differential, impulse, ...)

    • Data Type: STR_0D
    requirements.Psol_R

    Psol / R

    • Units: W/m
    • Data Type: FLT_0D
    requirements.beta_normal

    Normalized total plasma beta (MHD)

    • Data Type: FLT_0D
    requirements.coil_j_margin

    Magnet coil Jcrit / Jmax

    • Data Type: FLT_0D
    requirements.coil_stress_margin

    Magnet coil yieldstress / maxstress

    • Data Type: FLT_0D
    requirements.cost

    Total FPP cost

    • Units: $M
    • Data Type: FLT_0D
    requirements.flattop_duration

    Duration of the flattop (use Inf for steady-state)

    • Units: s
    • Data Type: FLT_0D
    requirements.h98y2

    H98y2 ITER elmy H-mode confinement scaling factor

    • Data Type: FLT_0D
    requirements.hds03

    Petty 2003 H-mode thermal energy confinement scaling factor

    • Data Type: FLT_0D
    requirements.lh_power_threshold_fraction

    Fraction of the LH power threshold

    • Data Type: FLT_0D
    requirements.ne_peaking

    On-axis electron density / volume-averaged electron denstiy

    • Data Type: FLT_0D
    requirements.power_electric_net

    Net electric power generated by the fusion power plant

    • Units: W
    • Data Type: FLT_0D
    requirements.q95

    Edge safety factor

    • Data Type: FLT_0D
    requirements.q_pol_omp

    Poloidal heat flux at the outer midplane

    • Units: W/m^2
    • Data Type: FLT_0D
    requirements.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    requirements.tritium_breeding_ratio

    Tritium breeding ratio of the whole plant

    • Data Type: FLT_0D
    runaway_electrons.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.code.library[:].name

    Name of software

    • Data Type: STR_0D
    runaway_electrons.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    runaway_electrons.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.code.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values", "1...N"]
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values", "1...N"]
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.ggd[:].temperature

    Reference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.distribution.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.distribution.gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["runaway_electrons.distribution.markers[:].orbit_integrals.expressions", "runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].orbit_integrals.n_tor", "runaway_electrons.distribution.markers[:].orbit_integrals.m_pol", "runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions", "runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit"]
    runaway_electrons.distribution.markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].coordinate_identifier"]
    runaway_electrons.distribution.markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.distribution.markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.e_field_critical_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.e_field_critical_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.e_field_critical_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.ggd_fluid[:].current_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].current_density[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].current_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].current_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].current_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].density[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].e_field_critical[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].e_field_critical[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_critical[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].pitch_angle[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].pitch_angle[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].pitch_angle[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.global_quantities.current_tor

    Total runaway current (toroidal component)

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.energy_kinetic

    Total runaway kinetic energy

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.current_density

    Runaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_compton

    Compton source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_dreicer

    Dreicer source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_hot_tail

    Hot tail source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_total

    Total source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_tritium

    Tritium source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.density

    Runaway electrons density

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.e_field_critical

    Critical electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.e_field_dreicer

    Dreicer electric field (parallel to magnetic field)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.energy_density_kinetic

    Runaways kinetic mean energy density

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.momentum_critical_avalanche

    Critical momentum for avalanche, Compton and tritium

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.momentum_critical_hot_tail

    Critical momentum for hot tail

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.pitch_angle

    Average pitch angle of the runaways distribution function (v_parallel/|v|)

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element"]
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    runaway_electrons.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    runaway_electrons.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    runaway_electrons.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    runaway_electrons.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    runaway_electrons.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_avalanche_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_avalanche_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.momentum_critical_avalanche_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_hot_tail_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_hot_tail_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.momentum_critical_hot_tail_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.profiles_1d[:].current_density

    Runaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_compton

    Compton source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_dreicer

    Dreicer source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_hot_tail

    Hot tail source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_total

    Total source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_tritium

    Tritium source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].density

    Runaway electrons density

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].e_field_critical

    Critical electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].e_field_dreicer

    Dreicer electric field (parallel to B)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].energy_density_kinetic

    Runaways kinetic mean energy density

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].momentum_critical_avalanche

    Critical momentum for avalanche, Compton and tritium

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].momentum_critical_hot_tail

    Critical momentum for hot tail

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].pitch_angle

    Average pitch angle of the runaways distribution function (v_parallel/|v|)

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].transport_perpendicular.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].transport_perpendicular.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].transport_perpendicular.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    sawteeth.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.code.library[:].name

    Name of software

    • Data Type: STR_0D
    sawteeth.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    sawteeth.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.code.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.crash_trigger

    Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N as follows. 1: crash triggered by the ideal kink criterion; 2: crash triggered by the ideal kink criterion including kinetic effects from fast particles; 31: crash triggered by the resistive kink criterion (meeting necessary conditions for reconnection); 32: crash triggered by the resistive kink criterion (resistive kink mode is unstable). The distinction between 31 and 32 only indicates whether (31) or (32) was the last criterion to be satisfied

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.magnetic_shear_q1

    Magnetic shear at surface q = 1, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_crash_time

    Time at which the previous sawtooth crash occured

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_crash_trigger

    Previous crash trigger. Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_period

    Previous sawtooth period

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_inversion

    Normalised toroidal flux coordinate at inversion radius

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_mixing

    Normalised toroidal flux coordinate at mixing radius

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_q1

    Normalised toroidal flux coordinate at surface q = 1

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    sawteeth.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    sawteeth.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    sawteeth.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    sawteeth.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    sawteeth.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    sawteeth.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    sawteeth.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    sawteeth.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].e_field_parallel

    Parallel electric field = average(E.B) / B0, where CoreProfiles/VacuumToroidal_Field/ B0

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    sawteeth.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons

    • Units: kg.m/s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_e

    Electron density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_e_fast

    Density of fast (non-thermal) electrons

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e

    Electron pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e_fast_parallel

    Fast (non-thermal) electron parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e_fast_perpendicular

    Fast (non-thermal) electron perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total

    Total ion pressure (sum over the ion species)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total_fast_parallel

    Fast (non-thermal) total ion (sum over the ion species) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total_fast_perpendicular

    Fast (non-thermal) total ion (sum over the ion species) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].psi_star_post_crash

    Psi* = psi - phi, after the sawtooth crash

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].psi_star_pre_crash

    Psi* = psi - phi, just before the sawtooth crash

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].q

    Safety factor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].t_e

    Electron temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    sawteeth.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    soft_x_rays.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].aperture[:].outline.x1"]
    soft_x_rays.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].brightness.data

    Data

    • Units: W.m^-2.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "soft_x_rays.channel[:].brightness.time"]
    soft_x_rays.channel[:].brightness.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    soft_x_rays.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].detector.outline.x1"]
    soft_x_rays.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].energy_band[:].energies"]
    soft_x_rays.channel[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    soft_x_rays.channel[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    soft_x_rays.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    soft_x_rays.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].filter_window[:].outline.x1"]
    soft_x_rays.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].filter_window[:].wavelengths"]
    soft_x_rays.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    soft_x_rays.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    soft_x_rays.channel[:].power.data

    Data

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "soft_x_rays.channel[:].power.time"]
    soft_x_rays.channel[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    soft_x_rays.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["soft_x_rays.channel[:].validity_timed.time"]
    soft_x_rays.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    soft_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    soft_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["soft_x_rays.time"]
    soft_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    soft_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    soft_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    soft_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    soft_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    soft_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    soft_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    soft_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.bucked

    Flag indicating if center stack elements bucked to one another

    • Data Type: INT_0D
    solid_mechanics.center_stack.displacement.oh

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.displacement.pl

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.displacement.tf

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.grid.r_oh

    Radial coordinate in OH layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.grid.r_pl

    Radial coordinate in plug layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.grid.r_tf

    Radial coordinate in TF layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.noslip

    Flag indicating if center stack elements are not allowed to slip with respect to one another

    • Data Type: INT_0D
    solid_mechanics.center_stack.plug

    Flag indicating if center stack has a plug

    • Data Type: INT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.oh

    Change in shape for OH structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.pl

    Change in shape for plug structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.tf

    Change in shape for TF structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.oh

    Maximum stress OH can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.pl

    Maximum stress plug can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.tf

    Maximum stress TF can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.oh

    Stiffness of OH structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.pl

    Stiffness of plug structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.tf

    Stiffness of TF structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.oh

    Average axial stress for OH layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.pl

    Average axial stress for plug layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.tf

    Average axial stress for TF layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.hoop.oh

    Hoop stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.hoop.pl

    Hoop stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.hoop.tf

    Hoop stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.stress.radial.oh

    Radial stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.radial.pl

    Radial stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.radial.tf

    Radial stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.stress.vonmises.oh

    Von Mises stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.vonmises.pl

    Von Mises stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.vonmises.tf

    Von Mises stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.channel[:].a

    Atomic mass measured by this channel

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spectrometer_mass.channel[:].current

    Collected current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].photomultiplier_voltage

    Voltage applied to the photomultiplier

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].pressure_partial

    Partial pressure (calibrated data)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].time

    Timebase for the dynamic nodes of this channel

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.channel[:].validity

    Indicator of the validity of the data. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning)

    • Data Type: INT_0D
    spectrometer_mass.channel[:].validity_timed

    Indicator of the validity of the data for each time slice. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Means problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning.)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_mass.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_mass.time"]
    spectrometer_mass.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.identifier

    ID of the spectrometer

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_mass.name

    Name of the spectrometer

    • Data Type: STR_0D
    spectrometer_mass.residual_spectrum[:].a

    Array of atomic masses

    • Units: Atomic Mass Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.residual_spectrum[:].current

    Collected current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.residual_spectrum[:].a"]
    spectrometer_mass.residual_spectrum[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_mass.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].aperture[:].outline.x1"]
    spectrometer_uv.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].detector.outline.x1"]
    spectrometer_uv.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector_layout.detector_dimensions

    Total detector dimension in each direction (horizontal, vertical)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_layout.pixel_dimensions

    Pixel dimension in each direction (horizontal, vertical)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_layout.pixel_n

    Number of pixels in each direction (horizontal, vertical)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_position_parameter.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].detector_position_parameter.time"]
    spectrometer_uv.channel[:].detector_position_parameter.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.curvature_radius

    Curvature radius of the spherical grating

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.groove_density

    Number of grooves per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.curvature_radius

    Curvature radius of the image surface

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].grating.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].grating.outline.x1"]
    spectrometer_uv.channel[:].grating.summit.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.summit.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.summit.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].intensity_spectrum.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_uv.channel[:].intensity_spectrum.time"]
    spectrometer_uv.channel[:].intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.amplitude_parameter

    Amplitude of the line of sight position parameter oscillation (in case moving_mode/index = 1)

    • Units: mixed
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].line_of_sight.period

    Period of the line of sight oscillation (in case moving_mode/index = 1)

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.position_parameter.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.position_parameter.time"]
    spectrometer_uv.channel[:].line_of_sight.position_parameter.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.second_point.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].line_of_sight.second_point.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    spectrometer_uv.channel[:].processed_line[:].intensity.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].processed_line[:].intensity.time"]
    spectrometer_uv.channel[:].processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].processed_line[:].radiance.time"]
    spectrometer_uv.channel[:].processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].wavelengths"]
    spectrometer_uv.channel[:].radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_uv.channel[:].radiance_spectral.time"]
    spectrometer_uv.channel[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].supply_high_voltage[:].object

    Name of the object connected to the power supply

    • Data Type: STR_0D
    spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time"]
    spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_uv.channel[:].validity_timed.data

    Data

    • Data Type: INT_2D
    • Coordinates: ["spectrometer_uv.channel[:].wavelengths", "spectrometer_uv.channel[:].validity_timed.time"]
    spectrometer_uv.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].wavelength_calibration.gain

    Gain

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].wavelength_calibration.offset

    Offset

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_uv.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_uv.time"]
    spectrometer_uv.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.etendue

    Etendue (geometric extent) of the optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    spectrometer_uv.etendue_method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].aperture[:].outline.x1"]
    spectrometer_visible.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector.outline.x1"]
    spectrometer_visible.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.circular.ellipticity

    Ellipticity

    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.circular.radius

    Radius of the circle

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.geometry_type

    Type of geometry used to describe the image (1:'outline', 2:'circular')

    • Data Type: INT_0D
    spectrometer_visible.channel[:].detector_image.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector_image.outline.r"]
    spectrometer_visible.channel[:].detector_image.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].detector_image.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector_image.outline.r"]
    spectrometer_visible.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1"]
    spectrometer_visible.channel[:].fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1"]
    spectrometer_visible.channel[:].fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.circular.ellipticity

    Ellipticity

    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.circular.radius

    Radius of the circle

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.geometry_type

    Type of geometry used to describe the image (1:'outline', 2:'circular')

    • Data Type: INT_0D
    spectrometer_visible.channel[:].fibre_image.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_image.outline.r"]
    spectrometer_visible.channel[:].fibre_image.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_image.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_image.outline.r"]
    spectrometer_visible.channel[:].filter_spectrometer.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_central

    Central wavelength of the filter

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_width

    Filter transmission function width (at 90% level)

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.output_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time"]
    spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time"]
    spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.photon_count.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.photon_count.time"]
    spectrometer_visible.channel[:].filter_spectrometer.photon_count.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].filter_spectrometer.sensitivity

    Photoelectric sensitivity of the detector. This is the conversion factor from the received power on the detector into electric voltage depending on the wavelength

    • Units: V.W^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].filter_spectrometer.wavelengths

    Array of wavelengths for radiance calibration

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3

    Third dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].geometry_matrix.interpolated.data

    Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector or head of an optic fibre). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.phi

    Toroidal angle (oriented counter-clockwise when viewing from above) of interpolation knots

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.r

    Major radius of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.z

    Height of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.voxel_map

    Voxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.

    • Data Type: INT_3D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1", "spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2", "spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3"]
    spectrometer_visible.channel[:].geometry_matrix.voxels_n

    Number of voxels defined in the voxel_map.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].geometry_matrix.with_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.with_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.with_reflections.data"]
    spectrometer_visible.channel[:].geometry_matrix.without_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.without_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.without_reflections.data"]
    spectrometer_visible.channel[:].grating_spectrometer.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.grating

    Number of grating lines per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.instrument_function

    Array of Gaussian widths and amplitudes which as a sum make up the instrument function. The instrument function is the shape that would be measured by a grating spectrometer if perfectly monochromatic line emission would be used as input. F(lambda) = 1 / sqrt (2*pi) * sum( instrumentfunction(1,i) / instrumentfunction(2,i) ) * exp( -lambda^2 / (2 * instrumentfunction(2,i)^2) ) ), whereby sum( instrumentfunction(1,i) ) = 1

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time"]
    spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time"]
    spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.slit_width

    Width of the slit (placed in the object focal plane)

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.gain

    Gain

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.offset

    Offset

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_fraction

    Fraction of cold neutrals for this isotope (ncoldneutrals/(ncoldneutrals+nhotneutrals))

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_temperature

    Temperature of cold neutrals for this isotope

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].density_ratio

    Ratio of the density of neutrals of this isotope over the summed neutral densities of all other isotopes described in the ../isotope array

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_fraction

    Fraction of hot neutrals for this isotope (nhotneutrals/(ncoldneutrals+nhotneutrals))

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_temperature

    Temperature of hot neutrals for this isotope

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].label

    String identifying the species (H, D, T, He3, He4)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.signal_to_noise

    Log10 of the ratio of the powers in two bands, one with the spectral lines of interest (signal) the other without spectral lines (noise).

    • Units: dB
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.time"]
    spectrometer_visible.channel[:].isotope_ratios.time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.validity

    Indicator of the validity of the isotope ratios for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.validity_timed

    Indicator of the validity of the isotope ratios as a function of time (0 means valid, negative values mean non-valid)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.time"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].light_collection_efficiencies.values

    Values of the light collection efficiencies

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    spectrometer_visible.channel[:].object_observed

    Main object observed by the channel

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1"]
    spectrometer_visible.channel[:].optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].polarization_spectroscopy.b_field_modulus

    Modulus of the magnetic field (always positive, irrespective of the sign convention for the B-field direction), obtained from Zeeman effect fit

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_r

    Lower Hybrid electric field component in the major radius direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_tor

    Lower Hybrid electric field component in the toroidal direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_z

    Lower Hybrid electric field component in the vertical direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.n_e

    Electron density, obtained from Stark broadening fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.temperature_cold_neutrals

    Fit of cold neutrals temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.temperature_hot_neutrals

    Fit of hot neutrals temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].polarization_spectroscopy.velocity_cold_neutrals

    Projection of the cold neutral velocity along the line of sight, positive when going from first point to second point of the line of sight

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.velocity_hot_neutrals

    Projection of the hot neutral velocity along the line of sight, positive when going from first point to second point of the line of sight

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarizer.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].polarizer.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].polarizer.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarizer.outline.x1"]
    spectrometer_visible.channel[:].polarizer.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer_active

    Indicator of whether a polarizer is present and active in the optical system (set to 1 in this case, set to 0 or leave empty ottherwise)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].validity_timed.time"]
    spectrometer_visible.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.time"]
    spectrometer_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.detector_layout

    Layout of the detector grid employed. Ex: '4x16', '4x32', '1x18'

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].aperture.outline.x1"]
    spectrometer_x_ray_crystal.channel[:].aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.centre

    Centre (in terms of absolute wavelength) of instrument function

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.intensity

    Scaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detector

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.scale

    Scale of Lorentzian instrument function (full width at half height)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.sigma

    Standard deviation of Gaussian instrument function

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.values

    Explicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a binned pixel of the detector, gives the detector pixel output in counts/seconds.

    • Units: sr.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths

    Array of wavelengths on which the instrument function is defined

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].wavelength

    Wavelength of incoming photons on each horizontal pixel of this bin.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].bin[:].z_pixel_range

    Vertical pixel index range indicating the corresponding binned detector area

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.camera_dimensions

    Total camera dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.identifier

    ID of the camera

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_dimensions

    Pixel dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixels_n

    Number of pixels in each direction (x1, x2)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.angle_bragg

    Bragg angle of the crystal

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.cut

    Miller indices characterizing the cut of the crystal (can be of length 3 or 4)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.identifier

    ID of the object

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].crystal.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].crystal.outline.x1"]
    spectrometer_x_ray_crystal.channel[:].crystal.radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.surface

    Surface of the object, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.thickness

    Thickness of the crystal

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.wavelength_bragg

    Bragg wavelength of the crystal

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_width

    Full width of the object in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_width

    Full width of the object in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].energies"]
    spectrometer_x_ray_crystal.channel[:].energies

    Array of energy values for tabulation of the detection efficiency

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].energy_bound_lower

    Lower energy bound for the photon detection, for each pixel (horizontal, vertical)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].energy_bound_upper

    Upper energy bound for the photon detection, for each pixel (horizontal, vertical)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].exposure_time

    Exposure time of the measurement

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].frame[:].counts_bin_n

    Number of counts detected on each pixel/bin of the binned frame during one exposure time

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].bin"]
    spectrometer_x_ray_crystal.channel[:].frame[:].counts_n

    Number of counts detected on each pixel of the frame during one exposure time

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.centre

    Centre (in terms of absolute wavelength) of instrument function

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.intensity

    Scaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detector

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.scale

    Scale of Lorentzian instrument function (full width at half height)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.sigma

    Standard deviation of Gaussian instrument function

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.values

    Explicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a pixel of the detector, gives the detector pixel output in counts/seconds.

    • Units: sr.m
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths

    Array of wavelengths on which the instrument function is defined

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.data

    Data

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.data

    Data

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].identifier

    ID of the object

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].surface

    Surface of the object, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_width

    Full width of the object in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_width

    Full width of the object in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].wavelength_frames

    Wavelength of incoming photons on each pixel of the frames, mainly varying accross the horizontal dimension of the frame. However a 2D map of the wavelength is given since it is not constant vertically due to the elliptical curvature of the photon iso-surfaces

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].z_frames

    Height of the observed zone at the focal plane in the plasma, corresponding to the vertical dimension of the frame

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.time"]
    spectrometer_x_ray_crystal.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spi.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spi.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spi.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spi.time"]
    spi.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.code.repository

    URL of software repository

    • Data Type: STR_0D
    spi.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spi.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spi.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spi.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spi.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spi.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spi.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spi.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spi.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spi.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spi.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spi.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spi.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spi.injector[:].fragment[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].fragment[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].velocity_r

    Major radius component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].velocity_tor

    Toroidal component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].velocity_z

    Vertical component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].volume

    Volume of the fragment

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragmentation_gas.atoms_n

    Total number of atoms of the gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.flow_rate

    Flow rate of the gas at the injector exit

    • Units: atoms.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragmentation_gas.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.species[:].fraction

    Atomic fraction of the species

    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].fragmentation_gas.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.temperature

    Gas temperature

    • Units: K
    • Data Type: FLT_0D
    spi.injector[:].identifier

    Identifier of the injector

    • Data Type: STR_0D
    spi.injector[:].injection_direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].injection_direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].injection_direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].name

    Name of the injector

    • Data Type: STR_0D
    spi.injector[:].optical_pellet_diagnostic.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.time_arrival

    Arrival time at the optical pellet diagnostic, for each object

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spi.injector[:].pellet.core.atoms_n

    Total number of atoms of desublimated gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].pellet.core.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.diameter

    Pellet diameter

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].pellet.length

    Pellet length (cylindrical pellet)

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].pellet.position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.shell.atoms_n

    Total number of atoms of desublimated gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].pellet.shell.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.velocity_r

    Major radius component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.velocity_shatter

    Norm of the velocity of the centre of mass of the pellet right before shattering

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].pellet.velocity_tor

    Toroidal component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.velocity_z

    Vertical component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].propellant_gas.atoms_n

    Total number of atoms of the gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.flow_rate

    Flow rate of the gas at the injector exit

    • Units: atoms.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].propellant_gas.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.species[:].fraction

    Atomic fraction of the species

    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].propellant_gas.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.temperature

    Gas temperature

    • Units: K
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.angle_major

    Angle between the cone direction and unitvectormajor

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.angle_minor

    Angle between the cone direction and unitvectorminor

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shattering_angle

    Impact (or grazing) angle of the pellet with the shattering element. It is the complementary of the incidence angle with the element surface at the shattering location

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].time_shatter

    Arrival time at the shattering unit

    • Units: s
    • Data Type: FLT_0D
    spi.injector[:].time_trigger

    Time of trigger request to the power supply according to the DMS sequence

    • Units: s
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_r

    Major radius component of the velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_tor

    Toroidal component of the velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_z

    Vertical component of the velocity velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    spi.shatter_cone_definition.description

    Verbose description

    • Data Type: STR_0D
    spi.shatter_cone_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spi.shatter_cone_definition.name

    Short string identifier

    • Data Type: STR_0D
    spi.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    stability.all_cleared

    True (1) if all stability limits are cleared, otherwise False (0)

    • Data Type: INT_1D
    • Coordinates: ["stability.time"]
    stability.collection[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    stability.collection[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    stability.collection[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    stability.model[:].cleared

    True (1) if a given stability limit is cleared, otherwise False (0)

    • Data Type: INT_1D
    • Coordinates: ["stability.time"]
    stability.model[:].fraction

    Fraction of limit

    • Data Type: FLT_1D
    • Coordinates: ["stability.time"]
    stability.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    stability.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    stability.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    stability.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    summary.boundary.distance_inner_outer_separatrices.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.distance_inner_outer_separatrices.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.elongation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.elongation.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.gap_limiter_wall.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.gap_limiter_wall.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.geometric_axis_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.geometric_axis_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.geometric_axis_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.geometric_axis_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.magnetic_axis_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.magnetic_axis_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.magnetic_axis_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.magnetic_axis_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.minor_radius.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.minor_radius.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_configuration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_configuration.value

    Value

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_inner_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_outer_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_outer_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_outer_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_outer_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.triangularity_lower.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.triangularity_lower.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.triangularity_upper.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.triangularity_upper.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.type.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.type.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.x_point_main.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.x_point_main.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.x_point_main.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.code.library[:].name

    Name of software

    • Data Type: STR_0D
    summary.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    summary.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.code.repository

    URL of software repository

    • Data Type: STR_0D
    summary.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.configuration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.configuration.value

    Value

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.mitigation_valve.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.mitigation_valve.value

    Value

    • Data Type: INT_0D
    summary.disruption.time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.time_half_ip.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time_half_ip.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.time_radiated_power_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time_radiated_power_max.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.vertical_displacement.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.vertical_displacement.value

    Value

    • Data Type: INT_0D
    summary.elms.frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.elms.frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.elms.type.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.elms.type.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_power_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_power_total.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ammonia.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ammonia_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.argon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.beryllium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.bottom.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.carbon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.deuterium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ethane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ethylene.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.helium_3.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.helium_4.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.hydrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_accumulated.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.krypton.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.lithium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane_carbon_13.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.midplane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.neon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.nitrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.oxygen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.propane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.silane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.top.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.total.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.tritium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.xenon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_prefill.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ammonia.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ammonia_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.argon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.beryllium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.bottom.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.carbon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.deuterium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ethane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ethylene.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.helium_3.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.helium_4.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.hydrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_prefill.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.krypton.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.lithium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane_carbon_13.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.midplane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.neon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.nitrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.oxygen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.propane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.silane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.top.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.total.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.tritium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.xenon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_rates.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ammonia.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ammonia_deuterated.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.argon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.beryllium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.bottom.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.carbon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.deuterium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ethane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ethylene.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.helium_3.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.helium_4.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.hydrogen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_rates.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.krypton.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.lithium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane_carbon_13.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane_deuterated.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.midplane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.neon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.nitrogen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.oxygen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.propane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.silane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.top.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.total.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.tritium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.xenon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.b0.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.b0.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_pol.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_pol_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_pol_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_norm.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_norm_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_norm_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_thermal_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_thermal_norm.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_alignment.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_alignment.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_bootstrap.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_bootstrap.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_non_inductive.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_non_inductive.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_ohm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_ohm.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.denergy_diamagnetic_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.denergy_diamagnetic_dt.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.denergy_thermal_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.denergy_thermal_dt.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_b_field_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_b_field_pol.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_diamagnetic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_diamagnetic.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_electrons_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_electrons_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_fast_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_fast_parallel.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_fast_perpendicular.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_fast_perpendicular.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_ion_total_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_ion_total_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_mhd.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_total.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.fusion_fluence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.fusion_fluence.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.fusion_gain.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.fusion_gain.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.greenwald_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.greenwald_fraction.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.h_98.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.h_98.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.h_mode.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.h_mode.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.ip.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.ip.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.li.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.li.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.li_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.li_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_bremsstrahlung.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_bremsstrahlung.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_line.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_line.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_loss.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_loss.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_ohm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_ohm.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated_inside_lcfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated_inside_lcfs.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated_outside_lcfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated_outside_lcfs.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_steady.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_steady.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_synchrotron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_synchrotron.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.psi_external_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.psi_external_average.value

    Value

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.q_95.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.q_95.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.r0.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.r0.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.global_quantities.ratio_tau_helium_fuel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.ratio_tau_helium_fuel.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.resistance.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.resistance.value

    Value

    • Units: ohm
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_energy.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_energy.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_energy_98.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_energy_98.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_helium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_helium.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_resistive.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_resistive.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.v_loop.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.v_loop.value

    Value

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.volume.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.volume.value

    Value

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].angle_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].angle_pol.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].angle_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].angle_tor.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].harmonic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].harmonic.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].polarisation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].polarisation.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].e_field_plus_minus_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].e_field_plus_minus_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].harmonic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].harmonic.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].k_perpendicular.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].k_perpendicular.value

    Value

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].n_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].n_tor.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].phase.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].phase.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].n_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].n_parallel.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].angle.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].angle.value

    Value

    • Units: rad
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].beam_current_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].beam_current_fraction.value

    Value

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "summary.time"]
    summary.heating_current_drive.nbi[:].beam_power_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].beam_power_fraction.value

    Value

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "summary.time"]
    summary.heating_current_drive.nbi[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].direction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].direction.value

    Value

    • Data Type: INT_0D
    summary.heating_current_drive.nbi[:].energy.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].energy.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].position.phi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.phi.value

    Value

    • Units: rad
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].position.r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.r.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].position.z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.z.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].species.a.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.a.value

    Value

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].species.label.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.label.value

    Value

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.z_n.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.z_n.value

    Value

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].tangency_radius.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].tangency_radius.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.power_additional.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_additional.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_ec.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_ec.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_ic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_ic.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_ec.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_ec.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_ic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_ic.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_lh.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_lh.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_nbi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_nbi.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_nbi_co_injected_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_nbi_co_injected_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_total.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_lh.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_lh.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_nbi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_nbi.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    summary.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    summary.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    summary.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    summary.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    summary.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    summary.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    summary.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    summary.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    summary.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    summary.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    summary.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    summary.kicks.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.kicks.occurrence.value

    Value

    • Data Type: INT_0D
    summary.limiter.material.description

    Verbose description

    • Data Type: STR_0D
    summary.limiter.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.limiter.material.name

    Short string identifier

    • Data Type: STR_0D
    summary.line_average.dn_e_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.dn_e_dt.value

    Value

    • Units: m^-3.s-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.isotope_fraction_hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.isotope_fraction_hydrogen.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.meff_hydrogenic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.meff_hydrogenic.value

    Value

    • Units: amu
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].flux_expansion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].flux_expansion.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].name.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].name.value

    Value

    • Data Type: STR_0D
    summary.local.divertor_target[:].power_flux_peak.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].power_flux_peak.value

    Value

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.flux_expansion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.flux_expansion.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.name.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.name.value

    Value

    • Data Type: STR_0D
    summary.local.limiter.power_flux_peak.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.power_flux_peak.value

    Value

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.b_field.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.b_field.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.effective_helical_ripple.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.effective_helical_ripple.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.iota.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.iota.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.plateau_factor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.plateau_factor.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.magnetic_shear_flag.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.magnetic_shear_flag.value

    Value

    • Data Type: INT_0D
    summary.midplane.description

    Verbose description

    • Data Type: STR_0D
    summary.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.midplane.name

    Short string identifier

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_average.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_average.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.coulomb_factor_pedestal_top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.coulomb_factor_pedestal_top.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.energy_thermal_pedestal_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.energy_thermal_pedestal_electron.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.energy_thermal_pedestal_ion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.energy_thermal_pedestal_ion.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.d_dpsi_norm.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.d_dpsi_norm_max.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.offset.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_height.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.separatrix.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.nustar_pedestal_top_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.nustar_pedestal_top_electron.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.parameters

    Parameters of the fit

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...5"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.offset.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_height.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.separatrix.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_magnetic_axis.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_magnetic_axis.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.d_dpsi_norm.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.d_dpsi_norm_max.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.offset.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_height.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.volume_inside_pedestal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.volume_inside_pedestal.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_average.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_average.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.coulomb_factor_pedestal_top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.coulomb_factor_pedestal_top.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_electron.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_ion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_ion.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.offset.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_height.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.separatrix.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.nustar_pedestal_top_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.nustar_pedestal_top_electron.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.parameters

    Parameters of the fit

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...5"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.offset.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_height.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.separatrix.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_magnetic_axis.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_magnetic_axis.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.alpha_experimental.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.alpha_experimental.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_critical.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.t_e_pedestal_top_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.t_e_pedestal_top_critical.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_critical.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.t_e_pedestal_top_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.t_e_pedestal_top_critical.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.offset.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_height.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.volume_inside_pedestal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.volume_inside_pedestal.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pellets.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pellets.occurrence.value

    Value

    • Data Type: INT_0D
    summary.plasma_duration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.plasma_duration.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.rmps.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.rmps.occurrence.value

    Value

    • Data Type: INT_0D
    summary.runaways.current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.runaways.current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.runaways.particles.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.runaways.particles.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.heat_flux_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.heat_flux_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.heat_flux_i_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.heat_flux_i_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.n_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.n_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.n_i_total_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.n_i_total_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.power_radiated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.power_radiated.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.pressure_neutral.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.pressure_neutral.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.t_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.t_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.t_i_average_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.t_i_average_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.stationary_phase_flag.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.stationary_phase_flag.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.tag.comment

    Any comment describing the content of the tagged list of entries

    • Data Type: STR_0D
    summary.tag.name

    Name of the tag

    • Data Type: STR_0D
    summary.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    summary.time_breakdown.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.time_breakdown.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.time_width

    In case the time-dependent quantities of this IDS are averaged over a time interval, this node is the width of this time interval (empty otherwise). By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.dn_e_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.dn_e_dt.value

    Value

    • Units: m^-3.s-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.isotope_fraction_hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.isotope_fraction_hydrogen.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.meff_hydrogenic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.meff_hydrogenic.value

    Value

    • Units: amu
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.wall.evaporation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.wall.evaporation.value

    Value

    • Data Type: STR_0D
    summary.wall.material.description

    Verbose description

    • Data Type: STR_0D
    summary.wall.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.wall.material.name

    Short string identifier

    • Data Type: STR_0D
    temporary.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.code.library[:].name

    Name of software

    • Data Type: STR_0D
    temporary.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    temporary.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["temporary.time"]
    temporary.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.code.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.constant_float0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float0d[:].value

    Value

    • Data Type: FLT_0D
    temporary.constant_float1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float1d[:].value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.constant_float2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float2d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    temporary.constant_float3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float3d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "1...N"]
    temporary.constant_float4d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float4d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float4d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float4d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N"]
    temporary.constant_float5d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float5d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float5d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float5d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_5D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N"]
    temporary.constant_float6d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float6d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float6d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float6d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_6D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N", "1...N"]
    temporary.constant_integer0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer0d[:].value

    Value

    • Data Type: INT_0D
    temporary.constant_integer1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer1d[:].value

    Value

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    temporary.constant_integer2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer2d[:].value

    Value

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    temporary.constant_integer3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer3d[:].value

    Value

    • Data Type: INT_3D
    • Coordinates: ["1...N", "1...N", "1...N"]
    temporary.constant_string0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_string0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_string0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_string0d[:].value

    Value

    • Data Type: STR_0D
    temporary.constant_string1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_string1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_string1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_string1d[:].value

    Value

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float1d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["temporary.dynamic_float1d[:].value.time"]
    temporary.dynamic_float1d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float2d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "temporary.dynamic_float2d[:].value.time"]
    temporary.dynamic_float2d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float3d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "temporary.dynamic_float3d[:].value.time"]
    temporary.dynamic_float3d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float4d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float4d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float4d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float4d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["1...N", "1...N", "1...N", "temporary.dynamic_float4d[:].value.time"]
    temporary.dynamic_float4d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float5d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float5d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float5d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float5d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_5D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "temporary.dynamic_float5d[:].value.time"]
    temporary.dynamic_float5d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float6d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float6d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float6d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float6d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_6D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N", "temporary.dynamic_float6d[:].value.time"]
    temporary.dynamic_float6d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer1d[:].value.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["temporary.dynamic_integer1d[:].value.time"]
    temporary.dynamic_integer1d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer2d[:].value.data

    Data

    • Data Type: INT_2D
    • Coordinates: ["1...N", "temporary.dynamic_integer2d[:].value.time"]
    temporary.dynamic_integer2d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer3d[:].value.data

    Data

    • Data Type: INT_3D
    • Coordinates: ["1...N", "1...N", "temporary.dynamic_integer3d[:].value.time"]
    temporary.dynamic_integer3d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    temporary.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    temporary.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    temporary.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    temporary.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    temporary.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    temporary.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    temporary.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    temporary.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    temporary.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    temporary.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    temporary.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    temporary.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.b_field_tor_vacuum_r.data

    Data

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["tf.b_field_tor_vacuum_r.time"]
    tf.b_field_tor_vacuum_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.code.library[:].name

    Name of software

    • Data Type: STR_0D
    tf.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    tf.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["tf.time"]
    tf.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.code.repository

    URL of software repository

    • Data Type: STR_0D
    tf.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.coil[:].conductor[:].cross_section.delta_phi

    Toroidal angles (relative to a reference point)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].cross_section.delta_r"]
    tf.coil[:].conductor[:].cross_section.delta_r

    Major radii (relative to a reference point)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].cross_section.delta_z

    Heights (relative to a reference point)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].cross_section.delta_r"]
    tf.coil[:].conductor[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].current.time"]
    tf.coil[:].conductor[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.centres.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.centres.r"]
    tf.coil[:].conductor[:].elements.centres.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.centres.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.centres.r"]
    tf.coil[:].conductor[:].elements.end_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.end_points.r"]
    tf.coil[:].conductor[:].elements.end_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.end_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.end_points.r"]
    tf.coil[:].conductor[:].elements.intermediate_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.intermediate_points.r"]
    tf.coil[:].conductor[:].elements.intermediate_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.intermediate_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.intermediate_points.r"]
    tf.coil[:].conductor[:].elements.names

    Name or description of every element

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.start_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.start_points.r"]
    tf.coil[:].conductor[:].elements.start_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.start_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.start_points.r"]
    tf.coil[:].conductor[:].elements.types

    Type of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circle

    • Data Type: INT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.names"]
    tf.coil[:].conductor[:].resistance

    conductor resistance

    • Units: Ohm
    • Data Type: FLT_0D
    tf.coil[:].conductor[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].voltage.time"]
    tf.coil[:].conductor[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].current.time"]
    tf.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].identifier

    Alphanumeric identifier of coil used for convenience

    • Data Type: STR_0D
    tf.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    tf.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    tf.coil[:].turns

    Number of total turns in a toroidal field coil. May be a fraction when describing the coil connections.

    • Data Type: FLT_0D
    tf.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].voltage.time"]
    tf.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coils_n

    Number of coils around the torus, in case is_periodic = 1

    • Data Type: INT_0D
    tf.delta_b_field_tor_vacuum_r.data

    Data

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["tf.delta_b_field_tor_vacuum_r.time"]
    tf.delta_b_field_tor_vacuum_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_r[:].values", "1...N"]
    tf.field_map[:].a_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_tor[:].values", "1...N"]
    tf.field_map[:].a_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_z[:].values", "1...N"]
    tf.field_map[:].a_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_r[:].values", "1...N"]
    tf.field_map[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_tor[:].values", "1...N"]
    tf.field_map[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_z[:].values", "1...N"]
    tf.field_map[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element"]
    tf.field_map[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element"]
    tf.field_map[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    tf.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    tf.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    tf.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    tf.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    tf.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    tf.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    tf.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    tf.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    tf.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    tf.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    tf.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    tf.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    tf.is_periodic

    Flag indicating whether coils are described one by one in the coil() structure (flag=0) or whether the coil structure represents only coils having different characteristics (flag = 1, n_coils must be filled in that case). In the latter case, the coil() sequence is repeated periodically around the torus.

    • Data Type: INT_0D
    tf.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    tf.r0

    Reference major radius of the device (from the official description of the device). This node is the placeholder for this official machine description quantity (typically the middle of the vessel at the equatorial midplane, although the exact definition may depend on the device)

    • Units: m
    • Data Type: FLT_0D
    tf.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].delta_position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].delta_position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].delta_position.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].delta_position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].distance_separatrix_midplane.time"]
    thomson_scattering.channel[:].distance_separatrix_midplane.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    thomson_scattering.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].n_e.time"]
    thomson_scattering.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    thomson_scattering.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    thomson_scattering.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    thomson_scattering.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    thomson_scattering.channel[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].t_e.time"]
    thomson_scattering.channel[:].t_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.code.library[:].name

    Name of software

    • Data Type: STR_0D
    thomson_scattering.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    thomson_scattering.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["thomson_scattering.time"]
    thomson_scattering.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.code.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    thomson_scattering.equilibrium_id.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.run

    Run number

    • Data Type: INT_0D
    thomson_scattering.equilibrium_id.data_entry.user

    Username

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.name

    IDS name

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.occurrence

    IDS occurrence

    • Data Type: INT_0D
    thomson_scattering.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    thomson_scattering.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    thomson_scattering.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    thomson_scattering.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    thomson_scattering.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    thomson_scattering.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    thomson_scattering.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    thomson_scattering.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    thomson_scattering.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    thomson_scattering.midplane.description

    Verbose description

    • Data Type: STR_0D
    thomson_scattering.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    thomson_scattering.midplane.name

    Short string identifier

    • Data Type: STR_0D
    thomson_scattering.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.value

    Value of the boundary condition. For ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].name

    Name of software

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    transport_solver_numerics.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["transport_solver_numerics.time"]
    transport_solver_numerics.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.code.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].current.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].current.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].current.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.time_step.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.convergence.time_step.time"]
    transport_solver_numerics.convergence.time_step.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d2psi_drho_tor2

    Second derivative of the poloidal flux profile with respect to the toroidal flux coordinate

    • Units: Wb.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dt.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dt.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dvolume_drho_tor_dt

    Partial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinate

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_drho_tor

    Derivative of the poloidal flux profile with respect to the toroidal flux coordinate

    • Units: Wb.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt

    Derivative of the poloidal flux profile with respect to time

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt_cphi

    Derivative of the poloidal flux profile with respect to time, at constant toroidal flux

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt_crho_tor_norm

    Derivative of the poloidal flux profile with respect to time, at constant normalised toroidal flux coordinate

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].drho_tor_dt

    Partial derivative of the toroidal flux coordinate profile with respect to time

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.derivatives_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.primary_coordinate.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.primary_coordinate.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.primary_coordinate.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.restart_files[:].descriptions

    Descriptions of the restart files

    • Data Type: STR_1D
    • Coordinates: ["transport_solver_numerics.restart_files[:].names"]
    transport_solver_numerics.restart_files[:].names

    Names of the restart files

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.restart_files[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.solver.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].name

    Name of the control parameter

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].value

    Value of the control parameter

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].name

    Name of the control parameter

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].value

    Value of the control parameter

    • Units: mixed
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].d_dvolume_drho_tor_dt

    Partial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinate

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].drho_tor_dt

    Partial derivative of the toroidal flux coordinate profile with respect to time

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].position

    Position, in terms of the primary coordinate, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed (in case of a single boundary condition).

    • Units: mixed
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].value

    Value of the boundary condition. For type/index = 1 to 3, only the first position in the vector is used. For type/index = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.solver_1d[:].equation[:].coefficient[:].profile

    Radial profile of the numerical coefficient

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d2_dr2

    Second order radial derivative with respect to the primary coordinate

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dr

    Radial derivative with respect to the primary coordinate

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt

    Time derivative

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cphi

    Derivative with respect to time, at constant toroidal flux (for current diffusion equation)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cr

    Derivative with respect to time, at constant primary coordinate coordinate (for current diffusion equation)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.ion_index

    If the primary quantity is related to a ion species, index of the corresponding species in the coreprofiles/profiles1d/ion array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.neutral_index

    If the primary quantity is related to a neutral species, index of the corresponding species in the coreprofiles/profiles1d/neutral array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.profile

    Profile of the primary quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.state_index

    If the primary quantity is related to a particular state (of an ion or a neutral species), index of the corresponding state in the coreprofiles/profiles1d/ion (or neutral)/state array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.solver_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step.time"]
    transport_solver_numerics.time_step.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step_average.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step_average.time"]
    transport_solver_numerics.time_step_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step_min.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step_min.time"]
    transport_solver_numerics.time_step_min.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time"]
    transport_solver_numerics.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    turbulence.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.code.library[:].name

    Name of software

    • Data Type: STR_0D
    turbulence.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    turbulence.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["turbulence.time"]
    turbulence.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.code.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.grid_2d[:].dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    turbulence.grid_2d[:].dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    turbulence.grid_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    turbulence.grid_2d_type.description

    Verbose description

    • Data Type: STR_0D
    turbulence.grid_2d_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    turbulence.grid_2d_type.name

    Short string identifier

    • Data Type: STR_0D
    turbulence.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    turbulence.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    turbulence.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    turbulence.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    turbulence.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    turbulence.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    turbulence.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    turbulence.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    turbulence.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    turbulence.profiles_2d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    turbulence.profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    turbulence.profiles_2d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    turbulence.profiles_2d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    turbulence.profiles_2d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    turbulence.profiles_2d[:].neutral[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    turbulence.profiles_2d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    turbulence.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.code.library[:].name

    Name of software

    • Data Type: STR_0D
    wall.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    wall.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["wall.time"]
    wall.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.code.repository

    URL of software repository

    • Data Type: STR_0D
    wall.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.description_2d[:].limiter.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].limiter.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].limiter.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].limiter.unit[:].component_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].component_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].limiter.unit[:].component_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].identifier

    Identifier of this unit. Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : ic_antenna/a1/bumpers refers to the bumpers of the a1 IC antenna

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].name

    Name of the limiter unit

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].limiter.unit[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].limiter.unit[:].outline.r"]
    wall.description_2d[:].limiter.unit[:].phi_extensions

    Simplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    wall.description_2d[:].limiter.unit[:].resistivity

    Resistivity of the limiter unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].mobile.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].mobile.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].mobile.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].mobile.unit[:].closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].mobile.unit[:].name

    Name of the mobile unit

    • Data Type: STR_0D
    wall.description_2d[:].mobile.unit[:].outline[:].r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].mobile.unit[:].outline[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_2d[:].mobile.unit[:].outline[:].z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].mobile.unit[:].outline[:].r"]
    wall.description_2d[:].mobile.unit[:].phi_extensions

    Simplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    wall.description_2d[:].mobile.unit[:].resistivity

    Resistivity of the mobile unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].vessel.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].vessel.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].vessel.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.centreline.r"]
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.outline_inner.r"]
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.outline_outer.r"]
    wall.description_2d[:].vessel.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.centreline.r"]
    wall.description_2d[:].vessel.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].element[:].j_tor.time"]
    wall.description_2d[:].vessel.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].element[:].outline.r"]
    wall.description_2d[:].vessel.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    wall.description_ggd[:].component[:].identifiers

    Identifiers of the components (described in the various gridsubsets). Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : icantenna/a1/bumpers refers to the bumpers of the a1 IC antenna

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].component[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].component[:].type[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].component[:].type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].a_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].a_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].a_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].a_field[:].r"]
    wall.description_ggd[:].ggd[:].a_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].a_field[:].r"]
    wall.description_ggd[:].ggd[:].a_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].e_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].e_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].e_field[:].r"]
    wall.description_ggd[:].ggd[:].e_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].e_field[:].r"]
    wall.description_ggd[:].ggd[:].e_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].j_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].j_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].j_total[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].j_total[:].r"]
    wall.description_ggd[:].ggd[:].j_total[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].j_total[:].r"]
    wall.description_ggd[:].ggd[:].j_total[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].phi_potential[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].power_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].power_density[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].power_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].power_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].power_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].psi[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].resistivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Ohm.m
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].resistivity[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].resistivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].resistivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].resistivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Ohm.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: K
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].temperature[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].v_biasing[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].v_biasing[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].material[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].material[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.descriptions

    Verbose description

    • Data Type: STR_1D
    • Coordinates: ["wall.description_ggd[:].material[:].grid_subset[:].identifiers.names"]
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.indices

    Integer identifiers (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_1D
    • Coordinates: ["wall.description_ggd[:].material[:].grid_subset[:].identifiers.names"]
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.names

    Short string identifiers

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].material[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].thickness[:].grid_subset[:].values", "1...N"]
    wall.description_ggd[:].thickness[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].thickness[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].type.name

    Short string identifier

    • Data Type: STR_0D
    wall.first_wall_enclosed_volume

    Volume available to gas or plasma enclosed by the first wall contour

    • Units: m^3
    • Data Type: FLT_0D
    wall.first_wall_power_flux_peak.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.first_wall_power_flux_peak.time"]
    wall.first_wall_power_flux_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.first_wall_surface_area

    First wall surface area

    • Units: m^2
    • Data Type: FLT_0D
    wall.global_quantities.current_tor

    Toroidal current flowing in the vacuum vessel

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.gas_puff

    Gas puff rate (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.particle_flux_from_plasma

    Particle flux from the plasma (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.particle_flux_from_wall

    Particle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), in equivalent electrons

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.electrons.power_inner_target

    Electron power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.power_outer_target

    Electron power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.pumping_speed

    Pumped particle flux (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.global_quantities.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].gas_puff

    Gas puff rate for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].incident_species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].incident_species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.global_quantities.neutral[:].incident_species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].incident_species[:].energies

    Array of energies of this incident species, on which the sputteringphysicalcoefficient is tabulated

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.global_quantities.neutral[:].incident_species[:].label

    String identifying the incident species (e.g. H, D, CD4, ...)

    • Data Type: STR_0D
    wall.global_quantities.neutral[:].incident_species[:].sputtering_chemical_coefficient

    Effective coefficient of chemical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].incident_species[:].sputtering_physical_coefficient

    Effective coefficient of physical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species and for various energies (second dimension)

    • Data Type: FLT_3D
    • Coordinates: ["1...3", "wall.global_quantities.neutral[:].incident_species[:].energies", "wall.time"]
    wall.global_quantities.neutral[:].label

    String identifying the species (e.g. H, D, CD4, ...)

    • Data Type: STR_0D
    wall.global_quantities.neutral[:].particle_flux_from_plasma

    Particle flux from the plasma for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].particle_flux_from_wall

    Particle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].pumping_speed

    Pumped particle flux for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].recycling_energy_coefficient

    Energy recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].recycling_particles_coefficient

    Particle recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].wall_inventory

    Wall inventory, i.e. cumulated exchange of neutral species between plasma and wall from t = 0, positive if a species has gone to the wall, for that species

    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_black_body

    Black body radiated power emitted from the wall (emissivity is included)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_conducted

    Power conducted by the plasma onto the wall

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_convected

    Power convected by the plasma onto the wall

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_currents

    Power deposited on the wall due to electric currents (positive means power is deposited on the target)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_density_inner_target_max

    Maximum power density on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_density_outer_target_max

    Maximum power density on the outer target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_incident

    Total power incident on the wall. This power is split in the various physical categories listed below

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_inner_target_ion_total

    Total ion (summed over ion species) power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_neutrals

    Net power from neutrals on the wall (positive means power is deposited on the wall)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_radiated

    Net radiated power from plasma onto the wall (incident-reflected)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_recombination_neutrals

    Power deposited on the wall due to recombination of neutrals into a ground state (e.g. molecules)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_recombination_plasma

    Power deposited on the wall due to recombination of plasma ions

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_to_cooling

    Power to cooling systems

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.temperature

    Wall temperature

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    wall.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    wall.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    wall.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    wall.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    wall.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    wall.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    wall.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    wall.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    wall.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    wall.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    wall.temperature_reference.data

    Reference temperature

    • Units: K
    • Data Type: FLT_0D
    wall.temperature_reference.description

    Description of how the reference temperature is defined : for which object, at which location, ...

    • Data Type: STR_0D
    wall.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.code.library[:].name

    Name of software

    • Data Type: STR_0D
    waves.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    waves.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["waves.time"]
    waves.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.code.repository

    URL of software repository

    • Data Type: STR_0D
    waves.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].electrons.power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].length

    Ray/beam curvilinear length

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].phase.angle

    Rotation angle for the phase ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].phase.curvature

    Inverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.psi

    Poloidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.theta

    Poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.parallel

    Normalized power flow in the direction parallel to the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.perpendicular

    Normalized power flow in the direction perpendicular to the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_initial

    Initial power in the ray/beam

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].spot.angle

    Rotation angle for the spot ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].spot.size

    Size of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r

    Wave vector component in the major radius direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r_norm

    Normalized wave vector component in the major radius direction = k_r / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor

    Wave vector component in the toroidal direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor_norm

    Normalized wave vector component in the toroidal direction = k_tor / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z

    Wave vector component in the vertical direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z_norm

    Normalized wave vector component in the vertical direction = k_z / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_parallel

    Parallel refractive index

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_perpendicular

    Perpendicular refractive index

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_tor

    Toroidal wave number, contains a single value if varyingntor = 0 to avoid useless repetition constant values. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive ntor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.varying_n_tor

    Flag telling whether n_tor is constant along the ray path (0) or varying (1)

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.minus[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.plus[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].current_tor

    Wave driven toroidal current from a stand alone calculation (not consistent with other sources)

    • Units: A
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].current_tor_n_tor

    Wave driven toroidal current from a stand alone calculation (not consistent with other sources) per toroidal mode number

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].electrons.distribution_assumption

    Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].electrons.power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].frequency

    Wave frequency

    • Units: Hz
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].distribution_assumption

    Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].global_quantities[:].power

    Total absorbed wave power

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].power_n_tor

    Absorbed wave power per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].identifier.antenna_name

    Name of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.

    • Data Type: STR_0D
    waves.coherent_wave[:].identifier.index_in_antenna

    Index of the wave (starts at 1), separating different waves generated from a single antenna.

    • Data Type: INT_0D
    waves.coherent_wave[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].current_parallel_density

    Flux surface averaged wave driven parallel current density = average(j.B) / B0, where B0 = vacuumtoroidalfield/b0.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].current_parallel_density_n_tor

    Flux surface averaged wave driven parallel current density, per toroidal mode number

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].current_tor_inside

    Wave driven toroidal current, inside a flux surface

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].current_tor_inside_n_tor

    Wave driven toroidal current, inside a flux surface, per toroidal mode number

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].k_perpendicular

    Perpendicular wave vector, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that kperpendicular = ave(kperpendicular.powerdensity) / ave(powerdensity), for every flux surface and every toroidal number

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_1d[:].power_density

    Flux surface averaged total absorbed wave power density (electrons + ion + fast populations)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].power_density_n_tor

    Flux surface averaged absorbed wave power density per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].power_inside

    Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].power_inside_n_tor

    Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.rho_tor

    Toroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.theta_geometric

    Geometrical poloidal angle

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.theta_straight

    Straight field line poloidal angle

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].grid.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].grid.type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_2d[:].power_density

    Total absorbed wave power density (electrons + ion + fast populations)

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].power_density_n_tor

    Absorbed wave power density per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].wave_solver_type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].wave_solver_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].wave_solver_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    waves.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    waves.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    waves.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    waves.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    waves.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    waves.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    waves.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    waves.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    waves.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    waves.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    waves.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    waves.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    workflow.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.code.library[:].name

    Name of software

    • Data Type: STR_0D
    workflow.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    workflow.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["workflow.time"]
    workflow.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.code.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    workflow.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    workflow.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    workflow.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    workflow.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    workflow.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    workflow.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    workflow.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    workflow.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    workflow.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    workflow.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    workflow.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    workflow.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    workflow.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.component[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.time_loop.component[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.time_loop.component[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.time_loop.component[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.time_loop.component[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.time_loop.component[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.time_loop.time_end

    Termination time for the workflow main time loop

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].component[:].control_float

    Array of real workflow control parameters used by this component (component specific)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.workflow_cycle[:].component[:].control_integer

    Array of integer workflow control parameters used by this component (component specific)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.workflow_cycle[:].component[:].execution_mode

    Component execution mode for current workflow cycle. 0 means the component is not executed and the workflow uses results from previous workflow cycle. 1 means the component is executed for this workflow cycle.

    • Data Type: INT_0D
    workflow.time_loop.workflow_cycle[:].component[:].index

    Index of the component in the ../../../component array

    • Data Type: INT_0D
    workflow.time_loop.workflow_cycle[:].component[:].time_interval_elapsed

    Simulation time interval for which this component has last computed its results

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].component[:].time_interval_request

    Simulation time interval for which this component is requested to compute its results

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    +
    GitHub
    amns_data.a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.code.library[:].name

    Name of software

    • Data Type: STR_0D
    amns_data.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    amns_data.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["amns_data.time"]
    amns_data.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.code.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].extrapolation_type

    Extrapolation strategy when leaving the domain. The first value of the vector describes the behaviour at lower bound, the second describes the at upper bound. Possible values: 0=none, report error; 1=boundary value; 2=linear extrapolation

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    amns_data.coordinate_system[:].coordinate[:].interpolation_type

    Interpolation strategy in this coordinate direction. Integer flag: 0=discrete (no interpolation); 1=linear; ...

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].label

    Description of coordinate (e.g. "Electron temperature")

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].spacing

    Flag for specific coordinate spacing (for optimization purposes). Integer flag: 0=undefined; 1=uniform; ...

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].transformation

    Coordinate transformation applied to coordinate values stored in coord. Integer flag: 0=none; 1=log10; 2=ln

    • Data Type: INT_0D
    amns_data.coordinate_system[:].coordinate[:].units

    Units of coordinate (e.g. eV)

    • Data Type: STR_0D
    amns_data.coordinate_system[:].coordinate[:].value_labels

    String description of discrete coordinate values (if interpolation_type=0). E.g., for spectroscopic lines, the spectroscopic description of the transition.

    • Data Type: STR_1D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.coordinate_system[:].coordinate[:].values

    Coordinate values

    • Units: units given by coordinate_system(:)/coordinate(:)/units
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    amns_data.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    amns_data.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    amns_data.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    amns_data.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    amns_data.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    amns_data.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    amns_data.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    amns_data.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    amns_data.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    amns_data.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    amns_data.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    amns_data.process[:].charge_state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    amns_data.process[:].charge_state[:].table_0d

    0D table describing the process data

    • Units: units given by process(:)/results_units
    • Data Type: FLT_0D
    amns_data.process[:].charge_state[:].table_1d

    1D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_1D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_2d

    2D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_2D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_3d

    3D table describing the process data

    • Units: units given by process(:)/results_units
    • Data Type: FLT_3D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_4d

    4D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_4D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_5d

    5D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_5D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].table_6d

    6D table describing the process data

    • Units: units given by process(i1)/results_units
    • Data Type: FLT_6D
    • Coordinates: ["amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values", "amns_data.coordinate_system[:].coordinate[:].values"]
    amns_data.process[:].charge_state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].charge_state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].citation

    Reference to publication(s)

    • Data Type: STR_0D
    amns_data.process[:].coordinate_index

    Index in tables_coord, specifying what coordinate systems to use for this process (valid for all tables)

    • Data Type: INT_0D
    amns_data.process[:].label

    String identifying the process (e.g. EI, RC, ...)

    • Data Type: STR_0D
    amns_data.process[:].products[:].charge

    Charge number of the participant

    • Data Type: FLT_0D
    amns_data.process[:].products[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    amns_data.process[:].products[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].label

    String identifying reaction participant (e.g. "D", "e", "W", "CD4", "photon", "n")

    • Data Type: STR_0D
    amns_data.process[:].products[:].mass

    Mass of the participant

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].products[:].metastable

    An array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    amns_data.process[:].products[:].metastable_label

    Label identifying in text form the metastable

    • Data Type: STR_0D
    amns_data.process[:].products[:].multiplicity

    Multiplicity in the reaction

    • Data Type: FLT_0D
    amns_data.process[:].products[:].relative_charge

    This is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundle

    • Data Type: INT_0D
    amns_data.process[:].products[:].role.description

    Verbose description

    • Data Type: STR_0D
    amns_data.process[:].products[:].role.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.process[:].products[:].role.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.process[:].provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].charge

    Charge number of the participant

    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].label

    String identifying reaction participant (e.g. "D", "e", "W", "CD4", "photon", "n")

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].mass

    Mass of the participant

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].metastable

    An array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    amns_data.process[:].reactants[:].metastable_label

    Label identifying in text form the metastable

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].multiplicity

    Multiplicity in the reaction

    • Data Type: FLT_0D
    amns_data.process[:].reactants[:].relative_charge

    This is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundle

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].role.description

    Verbose description

    • Data Type: STR_0D
    amns_data.process[:].reactants[:].role.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    amns_data.process[:].reactants[:].role.name

    Short string identifier

    • Data Type: STR_0D
    amns_data.process[:].result_label

    Description of the process result (rate, cross section, sputtering yield, ...)

    • Data Type: STR_0D
    amns_data.process[:].result_transformation

    Transformation of the process result. Integer flag: 0=no transformation; 1=10^; 2=exp()

    • Data Type: INT_0D
    amns_data.process[:].result_units

    Units of the process result

    • Data Type: STR_0D
    amns_data.process[:].source

    Filename or subroutine name used to provide this data

    • Data Type: STR_0D
    amns_data.process[:].table_dimension

    Table dimensionality of the process (1 to 6), valid for all charge states. Indicates which of the tables is filled (below the charge_state node)

    • Data Type: INT_0D
    amns_data.release[:].data_entry[:].description

    Description of this data entry

    • Data Type: STR_0D
    amns_data.release[:].data_entry[:].run

    Which run number is the active run number for this version

    • Data Type: INT_0D
    amns_data.release[:].data_entry[:].shot

    Shot number = Mass*1000+Nuclear_charge

    • Data Type: INT_0D
    amns_data.release[:].date

    Date of this release

    • Data Type: STR_0D
    amns_data.release[:].description

    Description of this release

    • Data Type: STR_0D
    amns_data.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    amns_data.z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    b_field_non_axisymmetric.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].name

    Name of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["b_field_non_axisymmetric.time"]
    b_field_non_axisymmetric.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.configuration

    In case of a constant (single time slice) b_field description, name of the corresponding scenario/configuration

    • Data Type: STR_0D
    b_field_non_axisymmetric.control_surface_names

    List of control surface names, refers to the ../timeslice/controlsurface index

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    b_field_non_axisymmetric.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    b_field_non_axisymmetric.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal

    Normal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal_fourier

    Fourier coefficients of the normal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_r

    R component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_tor

    Toroidal component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_z

    Z component of the vacuum error magnetic field on the various surface points

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r", "b_field_non_axisymmetric.time_slice[:].control_surface[:].phi"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor

    Toroidal mode number

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r"]
    b_field_non_axisymmetric.time_slice[:].control_surface[:].phi

    Toroidal angle array, on which the Fourier decomposition is carried out

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_r

    R component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_tor

    Toroidal component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.b_field_z

    Z component of the vacuum error magnetic field

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.phi", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    b_field_non_axisymmetric.time_slice[:].field_map.grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r"]
    b_field_non_axisymmetric.time_slice[:].field_map.ripple_amplitude

    Value of (bfieldmax-bfieldmin)/(bfieldmax+bfieldmin), where bfieldmax resp. bfieldmin) is the maximum (resp. minimum) of the magnetic field amplitude over a 2pi rotation in toroidal angle phi at a given R, Z position.

    • Data Type: FLT_2D
    • Coordinates: ["b_field_non_axisymmetric.time_slice[:].field_map.grid.r", "b_field_non_axisymmetric.time_slice[:].field_map.grid.z"]
    b_field_non_axisymmetric.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    balance_of_plant.Q_plant

    Electricity gain of the plant (ratio of net electric / plant electricity during operation)

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_net

    Net electric power

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.system[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_electric_plant_operation.system[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_electric_plant_operation.system[:].power

    Electrical power used to operate the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].power

    Electrical power used to operate the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_electric_plant_operation.total_power

    Total

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.generator_conversion_efficiency

    Conversion efficiency of thermal to electric power of the steam cycle

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.breeder

    The heat flow towards the breeder.

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.divertor

    The heat flow towards the divertor

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.heat_load.wall

    The heat flow towards the wall.

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.power_cycle_type

    Type of primary power cycle, :brayton = gas, :rankine = steam

    • Data Type: STR_0D
    balance_of_plant.power_plant.power_electric_generated

    The net electric power produced by the thermal plant, equal tot the power produced by turbines LESS the power consumed by pumps and compressors

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_plant.system[:].component[:].name

    Name of the component

    • Data Type: STR_0D
    balance_of_plant.power_plant.system[:].component[:].port[:].massflow

    Mass Flow Rate of the fluid

    • Units: kg/s
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].mechanicalPower

    Shaft power associated with the component, (+) = into the system, (-) = out of the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].name

    Name of the port

    • Data Type: STR_0D
    balance_of_plant.power_plant.system[:].component[:].port[:].pressure

    Fluid pressure

    • Units: Bar
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].temperature

    Fluid Temperature

    • Units: C
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].component[:].port[:].thermalPower

    Heattransfer rate of the component, (+) = into the system, (-) = out of the system

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.system[:].index

    Index of the system, used to generate functions

    • Data Type: INT_0D
    balance_of_plant.power_plant.system[:].name

    Name of the system

    • Data Type: STR_0D
    balance_of_plant.power_plant.total_heat_rejected

    The total heat flow being rejected from the thermal plant

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.power_plant.total_heat_supplied

    The total heat flow being supplied to the thermal Plant (Fusion thermal power).

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.thermal_efficiency_cycle

    The fractional thermal effiency of the power cycle. Calculated as 1-Qout/Qin

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.thermal_efficiency_plant

    The fractional thermal effiency of the entire BOP thermal plant, inlcudes all of the individual cycles. Calculated as 1-Qout/Qin

    • Data Type: FLT_1D
    • Coordinates: ["balance_of_plant.time"]
    balance_of_plant.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    barometry.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.code.library[:].name

    Name of software

    • Data Type: STR_0D
    barometry.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    barometry.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["barometry.time"]
    barometry.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.code.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.gauge[:].calibration_coefficient

    Coefficient used for converting raw signal into absolute pressure

    • Units: Pa
    • Data Type: FLT_0D
    barometry.gauge[:].name

    Name of the gauge

    • Data Type: STR_0D
    barometry.gauge[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    barometry.gauge[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    barometry.gauge[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    barometry.gauge[:].pressure.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["barometry.gauge[:].pressure.time"]
    barometry.gauge[:].pressure.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    barometry.gauge[:].type.description

    Verbose description

    • Data Type: STR_0D
    barometry.gauge[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    barometry.gauge[:].type.name

    Short string identifier

    • Data Type: STR_0D
    barometry.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    barometry.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    barometry.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    barometry.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    barometry.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    barometry.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    barometry.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    barometry.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    barometry.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    barometry.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    barometry.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    barometry.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    barometry.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    barometry.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    barometry.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    barometry.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    barometry.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    blanket.module[:].layer[:].material

    Material of the layer

    • Data Type: STR_0D
    blanket.module[:].layer[:].midplane_thickness

    Thickness of layer evaluated at the midplane

    • Units: m
    • Data Type: FLT_0D
    blanket.module[:].layer[:].name

    Name of the blanket layer

    • Data Type: STR_0D
    blanket.module[:].name

    Name of the blanket module

    • Data Type: STR_0D
    blanket.module[:].time_slice[:].peak_escape_flux

    Maximum neutron flux escaping from the back of the blanket module

    • Units: W/m^2
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].peak_wall_flux

    Maximum neutron flux at the first wall

    • Units: W/m^2
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_incident_neutrons

    Total incident neutron power on the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_incident_radiated

    Total incident radiative power on the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_extracted

    Total thermal power that is extracted from the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_neutrons

    Total neutron power (deposited + generated) in the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].power_thermal_radiated

    Total radiated power (incident - reflected) in the blanket module

    • Units: W
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    blanket.module[:].time_slice[:].tritium_breeding_ratio

    Number of tritium atoms for each incident neutron (TBR)

    • Data Type: FLT_0D
    blanket.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    blanket.tritium_breeding_ratio

    Number of tritium atoms created for each fusion neutron (TBR)

    • Data Type: FLT_1D
    • Coordinates: ["blanket.time"]
    bolometer.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    bolometer.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].aperture[:].outline.x1"]
    bolometer.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    bolometer.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].detector.outline.x1"]
    bolometer.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    bolometer.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    bolometer.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    bolometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bolometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    bolometer.channel[:].power.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.channel[:].power.time"]
    bolometer.channel[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    bolometer.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["bolometer.channel[:].validity_timed.time"]
    bolometer.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    bolometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    bolometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.grid.volume_element

    Volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["bolometer.grid.dim1", "bolometer.grid.dim2"]
    bolometer.grid_type.description

    Verbose description

    • Data Type: STR_0D
    bolometer.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    bolometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    bolometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    bolometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    bolometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    bolometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bolometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    bolometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bolometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    bolometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    bolometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    bolometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    bolometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    bolometer.power_density.data

    Data

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["bolometer.grid.dim1", "bolometer.grid.dim2", "bolometer.power_density.time"]
    bolometer.power_density.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bolometer.power_radiated_inside_lcfs

    Radiated power from the plasma inside the Last Closed Flux Surface, reconstructed from bolometry data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.power_radiated_total

    Total radiated power reconstructed from bolometry data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.power_radiated_validity

    Validity flag related to the radiated power reconstructions

    • Data Type: INT_1D
    • Coordinates: ["bolometer.time"]
    bolometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].filter.detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].filter.wavelengths"]
    bremsstrahlung_visible.channel[:].filter.wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].filter.wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].filter.wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].intensity.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].intensity.time"]
    bremsstrahlung_visible.channel[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    bremsstrahlung_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    bremsstrahlung_visible.channel[:].radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].radiance_spectral.time"]
    bremsstrahlung_visible.channel[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].zeff_line_average.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].zeff_line_average.time"]
    bremsstrahlung_visible.channel[:].zeff_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.channel[:].zeff_line_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    bremsstrahlung_visible.channel[:].zeff_line_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["bremsstrahlung_visible.channel[:].zeff_line_average.time"]
    bremsstrahlung_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["bremsstrahlung_visible.time"]
    bremsstrahlung_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    bremsstrahlung_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    bremsstrahlung_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    bremsstrahlung_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    bremsstrahlung_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.divertors.lower.installed

    1 if a lower divertor is installed

    • Data Type: INT_0D
    build.divertors.upper.installed

    1 if a upper divertor is installed

    • Data Type: INT_0D
    build.flux_swing.flattop

    Total flux required for the plasma flattop

    • Units: Wb
    • Data Type: FLT_0D
    build.flux_swing.pf

    Contribution of vertical field from PF coils to flux swing

    • Units: Wb
    • Data Type: FLT_0D
    build.flux_swing.rampup

    Total flux required for the plasma rampup

    • Units: Wb
    • Data Type: FLT_0D
    build.layer[:].area

    Cross sectional area of the layer

    • Units: m^2
    • Data Type: FLT_0D
    build.layer[:].end_radius

    End radius of the layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].identifier

    Integer to identify the same layer on the high-field-side and low-field-side

    • Data Type: INT_0D
    build.layer[:].material

    Material of the layer

    • Data Type: STR_0D
    build.layer[:].name

    Name of the layer

    • Data Type: STR_0D
    build.layer[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.layer[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.layer[:].outline.r"]
    build.layer[:].shape

    Integer to identify the physical shape of the layer

    • Data Type: INT_0D
    build.layer[:].shape_parameters

    List of the shape specific parameters for given shape type

    • Data Type: FLT_1D
    build.layer[:].side

    Integer set to -1 if layer is on the low-field-side and 1 if layer is on the high-field-side. 0 for plasma. 2 for inner (eg. OH) and 3 for outer (eg. cryostat)

    • Data Type: INT_0D
    build.layer[:].start_radius

    Start radius of the layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].thickness

    Radial thickness of layer

    • Units: m
    • Data Type: FLT_0D
    build.layer[:].type

    Layer type code

    1. vacuum (use this to set mimimum radius for OH)
    2. OH
    3. TF
    4. BL
    5. Shielding
    6. Wall

    -1) Vacuum vessel * Data Type: INT_0D

    build.layer[:].volume

    Volume of the layer

    • Units: m^3
    • Data Type: FLT_0D
    build.layer[:].volume_no_structures

    Volume of the layer without structures

    • Units: m^3
    • Data Type: FLT_0D
    build.oh.critical_b_field

    Critical magnetic field density to quench superconducting OH

    • Units: T
    • Data Type: FLT_0D
    build.oh.critical_j

    Critical current density to quench superconducting OH

    • Units: A/m^2
    • Data Type: FLT_0D
    build.oh.flattop_duration

    Estimated duration of the flattop

    • Units: s
    • Data Type: FLT_0D
    build.oh.max_b_field

    Maximum magnetic field in the OH solenoid, as required to satisfy rampup and flattop flux consumption

    • Units: T
    • Data Type: FLT_0D
    build.oh.max_j

    Maximum current density in the OH solenoid, as required to satisfy rampup and flattop flux consumption

    • Units: A/m^2
    • Data Type: FLT_0D
    build.oh.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the OH coils

    • Data Type: FLT_0D
    build.oh.technology.fraction_steel

    Fraction of stainless steel in the OH coils cross-sectional areas

    • Data Type: FLT_0D
    build.oh.technology.fraction_void

    Fraction of void in the OH coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.oh.technology.material

    Material of the OH coils

    • Data Type: STR_0D
    build.oh.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in OH coils

    • Data Type: FLT_0D
    build.oh.technology.temperature

    OH coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.oh.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the OH coils

    • Data Type: FLT_0D
    build.pf_active.rail[:].coils_cleareance

    Clereance that coils have from other structures

    • Units: m
    • Data Type: FLT_0D
    build.pf_active.rail[:].coils_number

    Number of coils on the rail

    • Data Type: INT_0D
    build.pf_active.rail[:].name

    Name of the coil rail

    • Data Type: STR_0D
    build.pf_active.rail[:].outline.distance

    Distance along the rail skipping gaps

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.pf_active.rail[:].outline.r"]
    build.pf_active.rail[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.pf_active.rail[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.pf_active.rail[:].outline.r"]
    build.pf_active.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the PF coils

    • Data Type: FLT_0D
    build.pf_active.technology.fraction_steel

    Fraction of stainless steel in the PF coils cross-sectional areas

    • Data Type: FLT_0D
    build.pf_active.technology.fraction_void

    Fraction of void in the PF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.pf_active.technology.material

    Material of the PF coils

    • Data Type: STR_0D
    build.pf_active.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in the PF coils

    • Data Type: FLT_0D
    build.pf_active.technology.temperature

    PF coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.pf_active.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the PF coils

    • Data Type: FLT_0D
    build.structure[:].area

    Cross sectional area of the structure

    • Units: m^2
    • Data Type: FLT_0D
    build.structure[:].identifier

    String to identify structure

    • Data Type: STR_0D
    build.structure[:].material

    Material of the structure

    • Data Type: STR_0D
    build.structure[:].name

    Name of the structure

    • Data Type: STR_0D
    build.structure[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    build.structure[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["build.structure[:].outline.r"]
    build.structure[:].toroidal_angles

    Toroidal position(s) of the structure

    • Units: rad
    • Data Type: FLT_1D
    build.structure[:].toroidal_extent

    Toroidal extent of the structure

    • Units: rad
    • Data Type: FLT_0D
    build.structure[:].type

    Structure type code

    • Data Type: INT_0D
    build.structure[:].volume

    Volume of the structure

    • Units: m^3
    • Data Type: FLT_0D
    build.tf.coils_n

    Number of TF coils around the torus

    • Data Type: INT_0D
    build.tf.critical_b_field

    Critical magnetic field to quench superconducting TF

    • Units: T
    • Data Type: FLT_0D
    build.tf.critical_j

    Critical current density to quench superconducting TF

    • Units: A/m^2
    • Data Type: FLT_0D
    build.tf.max_b_field

    Maximum magnetic field evaluated at the TF high-field side

    • Units: T
    • Data Type: FLT_0D
    build.tf.max_j

    Maximum current density in the TF solenoid

    • Units: A/m^2
    • Data Type: FLT_0D
    build.tf.ripple

    Fraction of toroidal field ripple evaluated at the outermost radius of the plasma chamber

    • Data Type: FLT_0D
    build.tf.technology.JxB_strain

    Fraction of maximum JxB strain over maximum total strain on the TF coils

    • Data Type: FLT_0D
    build.tf.technology.fraction_steel

    Fraction of stainless steel in the TF coils cross-sectional areas

    • Data Type: FLT_0D
    build.tf.technology.fraction_void

    Fraction of void in the TF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductor

    • Data Type: FLT_0D
    build.tf.technology.material

    Material of the TF coils

    • Data Type: STR_0D
    build.tf.technology.ratio_SC_to_copper

    Fraction of superconductor to copper cross-sectional areas in the TF coils

    • Data Type: FLT_0D
    build.tf.technology.temperature

    TF coils temperature

    • Units: K
    • Data Type: FLT_0D
    build.tf.technology.thermal_strain

    Fraction of thermal expansion strain over maximum total strain on the TF coils

    • Data Type: FLT_0D
    build.tf.wedge_thickness

    Thickness of the TF coils wedge evaluated

    • Units: m
    • Data Type: FLT_0D
    build.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.code.library[:].name

    Name of software

    • Data Type: STR_0D
    calorimetry.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    calorimetry.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.time"]
    calorimetry.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.code.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].identifier

    ID of the loop

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].mass_flow.data

    Data

    • Units: kg.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].mass_flow.time"]
    calorimetry.cooling_loop[:].mass_flow.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].mass_flow.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].mass_flow.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].mass_flow.time"]
    calorimetry.cooling_loop[:].name

    Name of the loop

    • Data Type: STR_0D
    calorimetry.cooling_loop[:].temperature_in.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_in.time"]
    calorimetry.cooling_loop[:].temperature_in.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].temperature_in.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].temperature_in.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_in.time"]
    calorimetry.cooling_loop[:].temperature_out.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_out.time"]
    calorimetry.cooling_loop[:].temperature_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.cooling_loop[:].temperature_out.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.cooling_loop[:].temperature_out.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.cooling_loop[:].temperature_out.time"]
    calorimetry.group[:].component[:].energy_cumulated.data

    Data

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].energy_cumulated.time"]
    calorimetry.group[:].component[:].energy_cumulated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].energy_cumulated.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].energy_cumulated.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].energy_cumulated.time"]
    calorimetry.group[:].component[:].energy_total.data

    Data

    • Units: J
    • Data Type: FLT_0D
    calorimetry.group[:].component[:].energy_total.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].identifier

    ID of the component

    • Data Type: STR_0D
    calorimetry.group[:].component[:].mass_flow.data

    Data

    • Units: kg.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].mass_flow.time"]
    calorimetry.group[:].component[:].mass_flow.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].mass_flow.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].mass_flow.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].mass_flow.time"]
    calorimetry.group[:].component[:].name

    Name of the component

    • Data Type: STR_0D
    calorimetry.group[:].component[:].power.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].power.time"]
    calorimetry.group[:].component[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].power.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].power.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].power.time"]
    calorimetry.group[:].component[:].temperature_in.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_in.time"]
    calorimetry.group[:].component[:].temperature_in.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].temperature_in.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].temperature_in.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_in.time"]
    calorimetry.group[:].component[:].temperature_out.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_out.time"]
    calorimetry.group[:].component[:].temperature_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].temperature_out.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].temperature_out.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].temperature_out.time"]
    calorimetry.group[:].component[:].transit_time.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["calorimetry.group[:].component[:].transit_time.time"]
    calorimetry.group[:].component[:].transit_time.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    calorimetry.group[:].component[:].transit_time.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    calorimetry.group[:].component[:].transit_time.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["calorimetry.group[:].component[:].transit_time.time"]
    calorimetry.group[:].identifier

    ID of the group

    • Data Type: STR_0D
    calorimetry.group[:].name

    Name of the group

    • Data Type: STR_0D
    calorimetry.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    calorimetry.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    calorimetry.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    calorimetry.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    calorimetry.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    calorimetry.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    calorimetry.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    calorimetry.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    calorimetry.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    calorimetry.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    calorimetry.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    calorimetry.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    calorimetry.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.calibration.luminance_to_temperature

    Luminance to temperature conversion table

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...2"]
    camera_ir.calibration.optical_temperature

    Temperature of the optical components (digital levels)

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_barrel

    Transmission of the optical barrel

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_mirror

    Transmission of the mirror

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.calibration.transmission_window

    Transmission of the window

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_ir.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_ir.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_ir.time"]
    camera_ir.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.fibre_bundle.fibre_positions.x1"]
    camera_ir.fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_ir.fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.fibre_bundle.geometry.outline.x1"]
    camera_ir.fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.frame[:].surface_temperature

    Surface temperature image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis). The size of this matrix is assumed to be constant over time

    • Units: K
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_ir.frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_ir.frame_analysis[:].distance_separatrix_midplane

    Distance between the measurement position and the separatrix, mapped along flux surfaces to the outboard midplane, in the major radius direction. Positive value means the measurement is outside of the separatrix.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.frame_analysis[:].power_flux_parallel

    Parallel heat flux received by the element monitored by the camera, along the distanceseparatrixmidplane coordinate

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.frame_analysis[:].distance_separatrix_midplane"]
    camera_ir.frame_analysis[:].sol_heat_decay_length

    Heat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031

    • Units: m
    • Data Type: FLT_0D
    camera_ir.frame_analysis[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_ir.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_ir.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_ir.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_ir.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_ir.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_ir.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_ir.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_ir.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_ir.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_ir.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_ir.midplane.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.midplane.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.name

    Name of the camera

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_ir.optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].geometry.outline.x1"]
    camera_ir.optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_ir.optical_element[:].material_properties.wavelengths"]
    camera_ir.optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_ir.optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    camera_ir.optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    camera_ir.optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_ir.optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    camera_ir.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].aperture[:].outline.x1"]
    camera_visible.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].columns_n

    Number of pixel columns in the horizontal direction

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].counts_to_radiance

    Counts to radiance factor, for each pixel of the detector. Includes both the transmission losses in the relay optics and the quantum efficiency of the camera itself, integrated over the wavelength range

    • Units: photons.m^-2.s^-1.sr^-1.counts^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].frame[:].image_raw

    Raw image (unprocessed) (digital levels). First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].frame[:].radiance

    Radiance image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Units: photons.m^-2.s^-1.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_visible.channel[:].detector[:].frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3

    Third dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.data

    Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector pixel). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi (third dimension of this array). The first two dimension correspond to the detector pixels : first dimension : line index (horizontal axis); second dimension: column index (vertical axis).

    • Units: m^-2
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.phi

    Toroidal angle (oriented counter-clockwise when viewing from above) of interpolation knots

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r

    Major radius of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.interpolated.z

    Height of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r"]
    camera_visible.channel[:].detector[:].geometry_matrix.voxel_map

    Voxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.

    • Data Type: INT_3D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1", "camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2", "camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3"]
    camera_visible.channel[:].detector[:].geometry_matrix.voxels_n

    Number of voxels defined in the voxel_map.

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.pixel_indices

    List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data", "1...2"]
    camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.pixel_indices

    List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data", "1...2"]
    camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data"]
    camera_visible.channel[:].detector[:].lines_n

    Number of pixel lines in the vertical direction

    • Data Type: INT_0D
    camera_visible.channel[:].detector[:].noise

    Detector noise (e.g. read-out noise) (rms counts per second exposure time)

    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].pixel_to_alpha

    Alpha angle of each pixel in the horizontal axis

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].pixel_to_beta

    Beta angle of each pixel in the vertical axis

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].detector[:].wavelength_lower

    Lower bound of the detector wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].detector[:].wavelength_upper

    Upper bound of the detector wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].fibre_bundle.fibre_positions.x1"]
    camera_visible.channel[:].fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].fibre_bundle.geometry.outline.x1"]
    camera_visible.channel[:].fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].geometry.outline.x1"]
    camera_visible.channel[:].optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["camera_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    camera_visible.channel[:].optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_visible.channel[:].optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    camera_visible.channel[:].optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.channel[:].optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.channel[:].optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.channel[:].viewing_angle_alpha_bounds

    Minimum and maximum values of alpha angle of the field of view, where alpha is the agle between the axis X3 and projection of the chord of view on the plane X1X3 counted clockwise from the top view of X2 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_visible.channel[:].viewing_angle_beta_bounds

    Minimum and maximum values of beta angle of the field of view, where beta is the angle between the axis X3 and projection of the chord of view on the plane X2X3 counted clockwise from the top view of X1 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_visible.time"]
    camera_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_visible.name

    Name of the camera

    • Data Type: STR_0D
    camera_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    camera_x_rays.aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.aperture.outline.x1"]
    camera_x_rays.aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.camera_dimensions

    Total camera dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.camera.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.identifier

    ID of the camera

    • Data Type: STR_0D
    camera_x_rays.camera.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_dimensions

    Pixel dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.pixel_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixel_position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.camera.pixels_n

    Number of pixels in each direction (x1, x2)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    camera_x_rays.camera.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.camera.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    camera_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    camera_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["camera_x_rays.time"]
    camera_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.detector_humidity.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.detector_humidity.time"]
    camera_x_rays.detector_humidity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.detector_temperature.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.detector_temperature.time"]
    camera_x_rays.detector_temperature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.energy_configuration_name

    Name of the chosen energy configuration (energy detection threshold)

    • Data Type: STR_0D
    camera_x_rays.energy_threshold_lower

    Lower energy detection threshold on each pixel of the detector (photons are counted only if their energy is above this value)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.identifier

    ID of the filter

    • Data Type: STR_0D
    camera_x_rays.filter_window.material.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.filter_window.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.filter_window.material.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.filter_window.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.filter_window.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.filter_window.outline.x1"]
    camera_x_rays.filter_window.photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["camera_x_rays.filter_window.wavelengths"]
    camera_x_rays.filter_window.radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    camera_x_rays.filter_window.thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.filter_window.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.filter_window.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    camera_x_rays.frame[:].counts_n

    Number of counts detected on each pixel during one exposure time. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    camera_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    camera_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    camera_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    camera_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    camera_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    camera_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    camera_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    camera_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    camera_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    camera_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    camera_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.name

    Name of the camera

    • Data Type: STR_0D
    camera_x_rays.photon_energy

    List of values of the photon energy (coordinate for quantum_effiency)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    camera_x_rays.pixel_status

    Status of each pixel : +1 for valid pixels, -1 for inactive pixels, -2 for mis-calibrated pixels.

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    camera_x_rays.quantum_efficiency

    Quantum efficiency of the detector, i.e. conversion factor multiplying the number of counts to obtain the number of photons impacting the detector, tabulated as a function of the photon energy, for each pixel of the detector. If all pixels have the same quantum efficiency, just set the size of the first and second dimensions to 1

    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "camera_x_rays.photon_energy"]
    camera_x_rays.readout_time

    Time used to read out each frame on the detector

    • Units: s
    • Data Type: FLT_0D
    camera_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    charge_exchange.aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    charge_exchange.aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.aperture.outline.x1"]
    charge_exchange.aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.a

    Mass of atom of the diagnostic neutral beam particle

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.doppler_shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].bes.doppler_shift.time"]
    charge_exchange.channel[:].bes.doppler_shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.label

    String identifying the diagnostic neutral beam particle

    • Data Type: STR_0D
    charge_exchange.channel[:].bes.lorentz_shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].bes.lorentz_shift.time"]
    charge_exchange.channel[:].bes.lorentz_shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.radiances.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].bes.radiances.time"]
    charge_exchange.channel[:].bes.radiances.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].bes.transition_wavelength

    Unshifted wavelength of the BES transition

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.z_ion

    Ion charge of the diagnostic neutral beam particle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].bes.z_n

    Nuclear charge of the diagnostic neutral beam particle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].a

    Mass of atom of the ion

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion[:].label

    String identifying the ion (e.g. H+, D+, T+, He+2, C+6, ...)

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].n_i_over_n_e.time"]
    charge_exchange.channel[:].ion[:].n_i_over_n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].n_i_over_n_e_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].t_i.time"]
    charge_exchange.channel[:].ion[:].t_i.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].t_i_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].t_i_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].t_i_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_pol.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].velocity_pol.time"]
    charge_exchange.channel[:].ion[:].velocity_pol.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].velocity_pol_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_pol_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].velocity_pol_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_tor.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion[:].velocity_tor.time"]
    charge_exchange.channel[:].ion[:].velocity_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion[:].velocity_tor_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].velocity_tor_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion[:].velocity_tor_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion[:].z_ion

    Ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].a

    Mass of atom of the fast ion

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].label

    String identifying the fast ion (e.g. H+, D+, T+, He+2, C+6, ...)

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].radiance.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].ion_fast[:].radiance.time"]
    charge_exchange.channel[:].ion_fast[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].ion_fast[:].radiance_spectral_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].ion_fast[:].transition_wavelength

    Unshifted wavelength of the fast ion charge exchange transition

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].z_ion

    Fast ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].ion_fast[:].z_n

    Nuclear charge of the fast ion

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    charge_exchange.channel[:].momentum_tor.data

    Data

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].momentum_tor.time"]
    charge_exchange.channel[:].momentum_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].momentum_tor_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].momentum_tor_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].momentum_tor_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    charge_exchange.channel[:].position.phi.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.phi.time"]
    charge_exchange.channel[:].position.phi.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].position.r.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.r.time"]
    charge_exchange.channel[:].position.r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].position.z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].position.z.time"]
    charge_exchange.channel[:].position.z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].grating

    Number of grating lines per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].instrument_function

    Array of Gaussian widths and amplitudes which as a sum make up the instrument fuction. IF(lambda) = sum( instrumentfunction(1,i)/sqrt(2 * pi * instrumentfunction(2,i)^2 ) * exp( -lambda^2/(2 * instrumentfunction(2,i)^2) ) ),whereby sum( instrumentfunction(1,i) ) = 1

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    charge_exchange.channel[:].spectrum[:].intensity_spectrum.data

    Data

    • Units: (photoelectrons).s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].intensity_spectrum.time"]
    charge_exchange.channel[:].spectrum[:].intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.data

    Data

    • Units: (photonelectrons).s^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].label

    String identifying the processed spectral line: Spectroscopy notation emitting element (e.g. D I, Be IV, W I, C VI), transition - if known - between round brackets (e.g. (3-2) ) and indication type of charge exchange - if applicable - between square brackets (e.g. [ACX] or [PCX]). Example for beryllium active charge exchange line at 468.5 nm: 'Be IV (8-6) [ACX]'. Example for impact excitation tungsten line coming from the plasma edge: 'W I'

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].shift.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].wavelength_central

    Unshifted central wavelength of the processed spectral line

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].processed_line[:].width.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].processed_line[:].width.time"]
    charge_exchange.channel[:].spectrum[:].processed_line[:].width.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].spectrum[:].wavelengths"]
    charge_exchange.channel[:].spectrum[:].radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].radiance_continuum.data

    Data

    • Units: m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].radiance_continuum.time"]
    charge_exchange.channel[:].spectrum[:].radiance_continuum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].radiance_spectral.data

    Data

    • Units: (photons) m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "charge_exchange.channel[:].spectrum[:].radiance_spectral.time"]
    charge_exchange.channel[:].spectrum[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].spectrum[:].slit_width

    Width of the slit (placed in the object focal plane)

    • Units: m
    • Data Type: FLT_0D
    charge_exchange.channel[:].spectrum[:].wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    charge_exchange.channel[:].spectrum[:].wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].t_i_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].t_i_average.time"]
    charge_exchange.channel[:].t_i_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].t_i_average_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].t_i_average_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].t_i_average_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].zeff.time"]
    charge_exchange.channel[:].zeff.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].zeff_line_average.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["charge_exchange.channel[:].zeff_line_average.time"]
    charge_exchange.channel[:].zeff_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    charge_exchange.channel[:].zeff_line_average_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_line_average_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].zeff_line_average_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.channel[:].zeff_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.channel[:].zeff_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.code.library[:].name

    Name of software

    • Data Type: STR_0D
    charge_exchange.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    charge_exchange.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["charge_exchange.time"]
    charge_exchange.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.code.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.etendue

    Etendue (geometric extent) of the optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    charge_exchange.etendue_method.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    charge_exchange.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    charge_exchange.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    charge_exchange.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    charge_exchange.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    charge_exchange.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    charge_exchange.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    charge_exchange.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    charge_exchange.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    charge_exchange.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    charge_exchange.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    charge_exchange.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    charge_exchange.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].name

    Name of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["coils_non_axisymmetric.time"]
    coils_non_axisymmetric.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.code.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].area

    Area of the conductor cross-section, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].height

    Full height of the rectangle in the binormal direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.binormal

    Coordinates along the binormal axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.normal"]
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].outline.normal

    Coordinate along the normal axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].radius_inner

    Inner radius of the annulus, used only if geometry_type/index = 5

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].cross_section[:].width

    Full width of the rectangle or square in the normal direction, when geometrytype/index = 3 or 4. Diameter of the circle when geometrytype/index = 2. Outer diameter of the annulus in case geometry_type/index = 5

    • Units: m
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.centres.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.end_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.start_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].elements.types"]
    coils_non_axisymmetric.coil[:].conductor[:].elements.types

    Type of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circle

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].conductor[:].resistance

    conductor resistance

    • Units: Ohm
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].conductor[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].conductor[:].voltage.time"]
    coils_non_axisymmetric.coil[:].conductor[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].current.time"]
    coils_non_axisymmetric.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.coil[:].identifier

    Alphanumeric identifier of coil

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    coils_non_axisymmetric.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].turns

    Number of total turns in the coil. May be a fraction when describing the coil connections.

    • Data Type: FLT_0D
    coils_non_axisymmetric.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["coils_non_axisymmetric.coil[:].voltage.time"]
    coils_non_axisymmetric.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    coils_non_axisymmetric.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    coils_non_axisymmetric.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    coils_non_axisymmetric.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    coils_non_axisymmetric.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.code.library[:].name

    Name of software

    • Data Type: STR_0D
    controllers.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    controllers.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["controllers.time"]
    controllers.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.code.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.controllability_metrics[:].data

    Array of scalar metrics in time

    • Data Type: FLT_1D
    controllers.controllability_metrics[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    controllers.controllability_metrics[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    controllers.controllability_metrics[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    controllers.controllability_metrics[:].time

    Controlability metric time

    • Units: s
    • Data Type: FLT_1D
    controllers.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    controllers.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    controllers.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    controllers.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    controllers.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    controllers.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    controllers.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    controllers.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    controllers.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    controllers.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    controllers.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    controllers.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    controllers.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    controllers.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    controllers.linear_controller[:].controller_class

    One of a known class of controllers

    • Data Type: STR_0D
    controllers.linear_controller[:].description

    Description of this controller

    • Data Type: STR_0D
    controllers.linear_controller[:].input_names

    Names of the input signals, following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].inputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.linear_controller[:].inputs.time"]
    controllers.linear_controller[:].inputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].name

    Name of this controller

    • Data Type: STR_0D
    controllers.linear_controller[:].output_names

    Names of the output signals following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].outputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.linear_controller[:].outputs.time"]
    controllers.linear_controller[:].outputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.d.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.d.time"]
    controllers.linear_controller[:].pid.d.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.i.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.i.time"]
    controllers.linear_controller[:].pid.i.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.p.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].output_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].pid.p.time"]
    controllers.linear_controller[:].pid.p.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].pid.tau.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["controllers.linear_controller[:].pid.tau.time"]
    controllers.linear_controller[:].pid.tau.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.a.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].statespace.a.time"]
    controllers.linear_controller[:].statespace.a.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.b.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].input_names", "controllers.linear_controller[:].statespace.b.time"]
    controllers.linear_controller[:].statespace.b.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.c.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].output_names", "controllers.linear_controller[:].statespace.c.time"]
    controllers.linear_controller[:].statespace.c.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.d.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["controllers.linear_controller[:].statespace.state_names", "controllers.linear_controller[:].output_names", "controllers.linear_controller[:].statespace.d.time"]
    controllers.linear_controller[:].statespace.d.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.deltat.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["controllers.linear_controller[:].statespace.deltat.time"]
    controllers.linear_controller[:].statespace.deltat.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.linear_controller[:].statespace.state_names

    Names of the states

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].controller_class

    One of a known class of controllers

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].description

    Description of this controller

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].function

    Method to be defined

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].input_names

    Names of the input signals, following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].inputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.nonlinear_controller[:].inputs.time"]
    controllers.nonlinear_controller[:].inputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].name

    Name of this controller

    • Data Type: STR_0D
    controllers.nonlinear_controller[:].output_names

    Output signal names following the SDN convention

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    controllers.nonlinear_controller[:].outputs.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "controllers.nonlinear_controller[:].outputs.time"]
    controllers.nonlinear_controller[:].outputs.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    controllers.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_instant_changes.change[:].profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.change[:].profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured"]
    core_instant_changes.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_instant_changes.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_instant_changes.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_instant_changes.time"]
    core_instant_changes.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_instant_changes.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_instant_changes.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_instant_changes.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_instant_changes.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_instant_changes.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_instant_changes.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_instant_changes.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_instant_changes.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_instant_changes.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_instant_changes.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_instant_changes.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_instant_changes.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_instant_changes.time"]
    core_instant_changes.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_profiles.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_profiles.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_profiles.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.covariance.data

    Covariance matrix

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.covariance.rows_uri", "core_profiles.covariance.rows_uri"]
    core_profiles.covariance.description

    Description of this covariance matrix

    • Data Type: STR_0D
    core_profiles.covariance.rows_uri

    List of URIs corresponding to the rows (1st dimension) of the covariance matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector it is sufficient to give a single URI where this vector is denoted using the (:) implicit notation, e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_profiles.global_quantities.beta_pol

    Poloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.beta_tor

    Toroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.beta_tor_norm

    Normalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA]

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_bootstrap

    Bootstrap current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_non_inductive

    Total non-inductive current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.current_ohmic

    Ohmic current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ejima

    Ejima coefficient : resistive psi losses divided by (mu0RIp). See S. Ejima et al, Nuclear Fusion, Vol.22, No.10 (1982), 1313

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.energy_diamagnetic

    Plasma energy content = 3/2 * integral over the plasma volume of the total perpendicular pressure

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion[:].n_i_volume_average

    Volume averaged density of this ion species (averaged over the plasma volume up to the LCFS)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion[:].t_i_volume_average

    Volume averaged temperature of this ion species (averaged over the plasma volume up to the LCFS)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.ion_time_slice

    Time slice of the profiles1d array used to define the ion composition of the globalquantities/ion array.

    • Units: s
    • Data Type: FLT_0D
    core_profiles.global_quantities.ip

    Total plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.li_3

    Internal inductance. The li3 definition is used, i.e. li3 = 2/R0/mu0^2/Ip^2 * int(Bp^2 dV).

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.n_e_volume_average

    Volume averaged electron density (average over the plasma volume up to the LCFS)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.polarized_fuel_fraction

    N/A

    • Data Type: FLT_0D
    core_profiles.global_quantities.resistive_psi_losses

    Resistive part of the poloidal flux losses, defined as the volume-averaged scalar product of the electric field and the ohmic current density, normalized by the plasma current and integrated in time from the beginning of the plasma discharge: int ( (int(Efieldtor.johmtor) dV) / Ip ) dt)

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_e_peaking

    Electron temperature peaking factor, defined as the Te value at the magnetic axis divided by the volume averaged Te (average over the plasma volume up to the LCFS)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_e_volume_average

    Volume averaged electron temperature (average over the plasma volume up to the LCFS)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.t_i_average_peaking

    Ion temperature (averaged over ion species and states) peaking factor, defined as the Ti value at the magnetic axis divided by the volume averaged Ti (average over the plasma volume up to the LCFS)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.v_loop

    LCFS loop voltage (positive value drives positive ohmic current that flows anti-clockwise when viewed from above)

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.global_quantities.z_eff_resistive

    Volume average plasma effective charge, estimated from the flux consumption in the ohmic phase

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_profiles.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_profiles.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_profiles.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_profiles.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_profiles.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_profiles.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_profiles.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_profiles.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.density_fit.measured"]
    core_profiles.profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    core_profiles.profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].grid.psi_norm

    Normalized poloidal magnetic flux

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    core_profiles.profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure

    Total pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].t_i_average_fit.measured"]
    core_profiles.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].grid.rho_tor_norm"]
    core_profiles.profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.profiles_1d[:].zeff_fit.measured"]
    core_profiles.profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].ion_index

    Index of the corresponding ion species in the ../../../profiles_1d/ion array

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_profiles.profiles_2d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].t_i_average

    Ion temperature (averaged on states and ion species)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.profiles_2d[:].zeff

    Effective charge

    • Data Type: FLT_2D
    • Coordinates: ["core_profiles.profiles_2d[:].grid.dim1", "core_profiles.profiles_2d[:].grid.dim2"]
    core_profiles.statistics[:].quantity_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].quantity_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].quantity_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics value

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path

    For Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3)

    • Data Type: INT_0D
    core_profiles.statistics[:].quantity_2d[:].statistics_type[:].value

    Value of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.statistics[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_profiles.statistics[:].time_width

    Width of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    core_profiles.statistics[:].uq_input_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].uq_input_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    core_profiles.statistics[:].uq_input_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    core_profiles.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_profiles.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_profiles.time"]
    core_profiles.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_sources.time"]
    core_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_sources.source[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_sources.source[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_sources.source[:].code.name

    Name of software used

    • Data Type: STR_0D
    core_sources.source[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["core_sources.source[:].code.output_flag.time"]
    core_sources.source[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.source[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_sources.source[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    core_sources.source[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_sources.source[:].global_quantities[:].current_parallel

    Parallel current driven

    • Units: A
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].electrons.particles

    Electron particle source

    • Units: s^-1
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].electrons.power

    Power coupled to electrons

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].power

    Total power coupled to the plasma

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].torque_tor

    Toroidal torque

    • Units: kg.m^2.s^-2
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].total_ion_particles

    Total ion particle source (summed over ion species)

    • Units: (ions).s^-1
    • Data Type: FLT_0D
    core_sources.source[:].global_quantities[:].total_ion_power

    Total power coupled to ion species (summed over ion species)

    • Units: W
    • Data Type: FLT_0D
    core_sources.source[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity due to this source

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_parallel

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy

    Source term for the electron energy equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles

    Source term for electron density equation

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.particles_inside

    Electron source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].electrons.power_inside

    Power coupled to electrons inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].grid.psi_norm

    Normalized poloidal magnetic flux

    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.source[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].energy

    Source term for the ion energy transport equation.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].fast_particles_energy

    Incoming energy of the fast ion particles (eg. fusion 3.5MeV alphas or 1MeV nbi)

    • Units: eV
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].momentum.diamagnetic

    Diamagnetic component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.parallel

    Parallel component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.poloidal

    Poloidal component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.radial

    Radial component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal

    Toroidal component

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.explicit_part

    Explicit part of the source term

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].ion[:].particles

    Source term for ion density equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].particles_inside

    Ion source inside the flux surface. Cumulative volume integral of the source term for the ion density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].power_inside

    Power coupled to the ion species inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy

    Source terms for the charge state energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles

    Source term for the charge state density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.explicit_part

    Explicit part of the source term

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_inside

    State source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].power_inside

    Power coupled to the state inside the flux surface. Cumulative volume integral of the source term for the electron energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].j_parallel

    Parallel current density source, average(J.B) / B0, where B0 = coresources/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].momentum_tor

    Source term for total toroidal momentum equation

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].momentum_tor_j_cross_b_field

    Contribution to the toroidal momentum source term (already included in the momentum_tor node) corresponding to the toroidal torques onto the thermal plasma due to Lorentz force associated with radial currents. These currents appear as return-currents (enforcing quasi-neutrality, div(J)=0) balancing radial currents of non-thermal particles, e.g. radial currents of fast and trapped neutral-beam-ions.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].energy

    Source term for the neutral energy transport equation.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].particles

    Source term for neutral density equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].energy

    Source terms for the state energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].particles

    Source term for the state density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_sources.source[:].profiles_1d[:].torque_tor_inside

    Toroidal torque inside the flux surface. Cumulative volume integral of the source term for the total toroidal momentum equation

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy

    Source term for the total (summed over ion species) energy equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.explicit_part

    Explicit part of the source term

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.implicit_part

    Implicit part of the source term, i.e. to be multiplied by the equation's primary quantity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].profiles_1d[:].total_ion_power_inside

    Total power coupled to ion species (summed over ion species) inside the flux surface. Cumulative volume integral of the source term for the total ion energy equation

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    core_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    core_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    core_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_sources.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_sources.time"]
    core_sources.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    core_transport.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.code.library[:].name

    Name of software

    • Data Type: STR_0D
    core_transport.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    core_transport.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["core_transport.time"]
    core_transport.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.code.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    core_transport.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    core_transport.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    core_transport.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    core_transport.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    core_transport.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_transport.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    core_transport.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    core_transport.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    core_transport.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    core_transport.model[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    core_transport.model[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    core_transport.model[:].code.name

    Name of software used

    • Data Type: STR_0D
    core_transport.model[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["core_transport.model[:].code.output_flag.time"]
    core_transport.model[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    core_transport.model[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    core_transport.model[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    core_transport.model[:].comment

    Any comment describing the model

    • Data Type: STR_0D
    core_transport.model[:].flux_multiplier

    Multiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2

    • Data Type: FLT_0D
    core_transport.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    core_transport.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    core_transport.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].e_field_radial

    Radial component of the electric field (calculated e.g. by a neoclassical model)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].electrons.particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_d.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_d.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_d.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_d.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_flux.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_flux.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_flux.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_flux.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_v.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].grid_v.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.model[:].profiles_1d[:].grid_v.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].grid_v.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].ion[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flow_damping_rate

    Damping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].momentum_tor.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].momentum_tor.flux

    Flux

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].momentum_tor.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    core_transport.model[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    core_transport.model[:].profiles_1d[:].total_ion_energy.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].total_ion_energy.flux

    Flux

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm"]
    core_transport.model[:].profiles_1d[:].total_ion_energy.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm"]
    core_transport.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    core_transport.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["core_transport.time"]
    core_transport.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    costing.availability

    Availability fraction of the plant

    • Data Type: FLT_0D
    costing.construction_start_year

    Year that plant construction begins

    • Units: year
    • Data Type: INT_0D
    costing.cost_decommissioning.cost

    Cost to decomission the plant

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].cost

    Cost to decommission the system

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].name

    Name of the system to decommission

    • Data Type: STR_0D
    costing.cost_decommissioning.system[:].subsystem[:].cost

    Cost to decommission the subsystem

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_decommissioning.system[:].subsystem[:].name

    Name of the subsystem to decommission

    • Data Type: STR_0D
    costing.cost_direct_capital.cost

    Total direct capital

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].cost

    Cost of the system

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].name

    Name of the system

    • Data Type: STR_0D
    costing.cost_direct_capital.system[:].subsystem[:].cost

    Cost of the subsystem

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_direct_capital.system[:].subsystem[:].name

    Name of the subsystem

    • Data Type: STR_0D
    costing.cost_lifetime

    Total cost of fusion power plant

    • Units: $M
    • Data Type: FLT_0D
    costing.cost_operations.system[:].name

    Name of the system

    • Data Type: STR_0D
    costing.cost_operations.system[:].subsystem[:].name

    Name of the subsystem

    • Data Type: STR_0D
    costing.cost_operations.system[:].subsystem[:].yearly_cost

    Cost of the subsystem per year

    • Units: $M/year
    • Data Type: FLT_0D
    costing.cost_operations.system[:].yearly_cost

    Cost of system per year

    • Units: $M/year
    • Data Type: FLT_0D
    costing.cost_operations.yearly_cost

    Anual cost to operate the plant

    • Units: $M/year
    • Data Type: FLT_0D
    costing.future.inflation_rate

    Predicted average rate of future inflation

    • Data Type: FLT_0D
    costing.future.learning.hts.learning_rate

    Learning rate for ReBCO technology production

    • Data Type: FLT_0D
    costing.future.learning.hts.production_increase

    Factor by which production of ReBCO multiplies

    • Data Type: FLT_0D
    costing.levelized_CoE

    Levelized cost of electiricity (total cost / total electricy generated)

    • Units: $/kWh
    • Data Type: FLT_0D
    costing.plant_lifetime

    Lifetime of the plant

    • Units: year
    • Data Type: INT_0D
    costing.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.code.library[:].name

    Name of software

    • Data Type: STR_0D
    cryostat.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    cryostat.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["cryostat.time"]
    cryostat.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.code.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r"]
    cryostat.description_2d[:].cryostat.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r"]
    cryostat.description_2d[:].cryostat.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].cryostat.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].cryostat.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r"]
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    cryostat.description_2d[:].thermal_shield.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    cryostat.description_2d[:].thermal_shield.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    cryostat.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    cryostat.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    cryostat.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    cryostat.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    cryostat.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    cryostat.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    cryostat.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    cryostat.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    cryostat.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    cryostat.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    cryostat.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    cryostat.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    cryostat.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_description.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    dataset_description.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    dataset_description.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    dataset_description.data_entry.run

    Run number

    • Data Type: INT_0D
    dataset_description.data_entry.user

    Username

    • Data Type: STR_0D
    dataset_description.dd_version

    Version of the physics data dictionary of this dataset

    • Data Type: STR_0D
    dataset_description.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    dataset_description.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    dataset_description.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    dataset_description.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    dataset_description.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    dataset_description.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    dataset_description.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_description.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_description.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    dataset_description.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_description.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    dataset_description.imas_version

    Version of the IMAS infrastructure used to produce this data entry. Refers to the global IMAS repository which links to versions of every infrastructure tools

    • Data Type: STR_0D
    dataset_description.parent_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    dataset_description.parent_entry.pulse

    Pulse number

    • Data Type: INT_0D
    dataset_description.parent_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    dataset_description.parent_entry.run

    Run number

    • Data Type: INT_0D
    dataset_description.parent_entry.user

    Username

    • Data Type: STR_0D
    dataset_description.pulse_time_begin

    Date and time (UTC) at which the pulse started on the experiment, expressed in a human readable form (ISO 8601) : the format of the string shall be : YYYY-MM-DDTHH:MM:SSZ. Example : 2020-07-24T14:19:00Z

    • Data Type: STR_0D
    dataset_description.pulse_time_begin_epoch.nanoseconds

    Elapsed nanoseconds since the time in seconds indicated above

    • Data Type: INT_0D
    dataset_description.pulse_time_begin_epoch.seconds

    Elapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)

    • Data Type: INT_0D
    dataset_description.pulse_time_end_epoch.nanoseconds

    Elapsed nanoseconds since the time in seconds indicated above

    • Data Type: INT_0D
    dataset_description.pulse_time_end_epoch.seconds

    Elapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)

    • Data Type: INT_0D
    dataset_description.simulation.comment_after

    Comment made at the end of a simulation

    • Data Type: STR_0D
    dataset_description.simulation.comment_before

    Comment made when launching a simulation

    • Data Type: STR_0D
    dataset_description.simulation.time_begin

    Start time

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_begun

    Actual wall-clock time simulation started

    • Units: UTC
    • Data Type: STR_0D
    dataset_description.simulation.time_current

    Current time of the simulation

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_end

    Stop time

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_ended

    Actual wall-clock time simulation finished

    • Units: UTC
    • Data Type: STR_0D
    dataset_description.simulation.time_restart

    Time of the last restart done during the simulation

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.time_step

    Time interval between main steps, e.g. storage step (if relevant and constant)

    • Units: s
    • Data Type: FLT_0D
    dataset_description.simulation.workflow

    Description of the workflow which has been used to produce this data entry (e.g. copy of the Kepler MOML if using Kepler)

    • Data Type: STR_0D
    dataset_description.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_fair.identifier

    Persistent identifier allowing to cite this data in a public and persistent way, should be provided as HTTP URIs

    • Data Type: STR_0D
    dataset_fair.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    dataset_fair.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    dataset_fair.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    dataset_fair.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    dataset_fair.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    dataset_fair.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    dataset_fair.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    dataset_fair.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    dataset_fair.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    dataset_fair.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_fair.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    dataset_fair.is_referenced_by

    List of documents (e.g. publications) or datasets making use of this data entry (e.g. PIDs of other datasets using this data entry as input)

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    dataset_fair.is_replaced_by

    Persistent identifier referencing the new version of this data (replacing the present version)

    • Data Type: STR_0D
    dataset_fair.license

    License(s) under which the data is made available (license description or, more convenient, publicly accessible URL pointing to the full license text)

    • Data Type: STR_0D
    dataset_fair.replaces

    Persistent identifier referencing the previous version of this data

    • Data Type: STR_0D
    dataset_fair.rights_holder

    The organisation owning or managing rights over this data

    • Data Type: STR_0D
    dataset_fair.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    dataset_fair.valid

    Date range during which the data is or was valid. Expressed as YYYY-MM-DD/YYYY-MM-DD, where the former (resp. latter) date is the data at which the data started (resp. ceased) to be valid. If the data is still valid, the slash should still be present, i.e. indicate the validity start date with YYYY-MM-DD/. If the data ceased being valid but there is no information on the validity start date, indicate /YYYY-MM-DD.

    • Data Type: STR_0D
    disruption.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.code.library[:].name

    Name of software

    • Data Type: STR_0D
    disruption.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    disruption.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["disruption.time"]
    disruption.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.code.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.global_quantities.current_halo_pol

    Poloidal halo current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.current_halo_tor

    Toroidal halo current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_ohm

    Total ohmic cumulated energy (integral of the power over the disruption duration)

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_ohm_halo

    Ohmic cumulated energy (integral of the power over the disruption duration) in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_parallel_halo

    Cumulated parallel energy (integral of the heat flux parallel power over the disruption duration) in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_radiated_electrons_impurities

    Total cumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.energy_radiated_electrons_impurities_halo

    Cumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities in the halo region

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_ohm

    Total ohmic power

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_ohm_halo

    Ohmic power in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_parallel_halo

    Power of the parallel heat flux in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_radiated_electrons_impurities

    Total power radiated by electrons on impurities

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.power_radiated_electrons_impurities_halo

    Power radiated by electrons on impurities in the halo region

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.global_quantities.psi_halo_boundary

    Poloidal flux at halo region boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.halo_currents[:].active_wall_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].active_wall_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].current_halo_pol

    Poloidal halo current crossing through this area

    • Units: A
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].end_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].end_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].start_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].area[:].start_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    disruption.halo_currents[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    disruption.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    disruption.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    disruption.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    disruption.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    disruption.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    disruption.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    disruption.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    disruption.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    disruption.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    disruption.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    disruption.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    disruption.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    disruption.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    disruption.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    disruption.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    disruption.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    disruption.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    disruption.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    disruption.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].j_runaways

    Runaways parallel current density = average(j.B) / B0, where B0 = Disruption/VacuumToroidalField/ B0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].power_density_conductive_losses

    Power density of conductive losses to the wall (positive sign for losses)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].power_density_radiative_losses

    Power density of radiative losses (positive sign for losses)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["disruption.profiles_1d[:].grid.rho_tor_norm"]
    disruption.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    disruption.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    disruption.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["disruption.time"]
    disruption.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    distribution_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    distribution_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    distribution_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    distribution_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    distribution_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    distribution_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    distribution_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    distribution_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distribution_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    distribution_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    distribution_sources.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.source[:].ggd[:].discrete

    List of indices of grid spaces (refers to ../grid/space) for which the source is discretely distributed. For example consider a source of 3.5 MeV alpha particles provided on a grid with two coordinates (spaces); rho_tor and energy. To specify that the source is given at energies exactly equal to 3.5 MeV, let discret have length 1 and set discrete(1)=2 since energy is dimension number 2. The source is then proportional to delta( 1 - energy / 3.5MeV ), where delta is the direct delta distribution. Discrete dimensions can only be used when the grid is rectangular.

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distribution_sources.source[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: (m.s^-1)^-3.m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["distribution_sources.source[:].ggd[:].particles[:].values", "1...N"]
    distribution_sources.source[:].ggd[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distribution_sources.source[:].ggd[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: (m.s^-1)^-3.m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].particles

    Particle source rate

    • Units: s^-1
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].power

    Total power of the source

    • Units: W
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.particles

    Particle losses due to shinethrough

    • Units: s^-1
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.power

    Power losses due to shinethrough

    • Units: W
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].shinethrough.torque_tor

    Toroidal torque losses due to shinethrough

    • Units: N.m
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].global_quantities[:].torque_tor

    Total toroidal torque of the source

    • Units: N.m
    • Data Type: FLT_0D
    distribution_sources.source[:].gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["distribution_sources.source[:].markers[:].orbit_integrals.expressions", "distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].orbit_integrals.n_tor", "distribution_sources.source[:].markers[:].orbit_integrals.m_pol", "distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions", "distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit"]
    distribution_sources.source[:].markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distribution_sources.source[:].markers[:].weights", "distribution_sources.source[:].markers[:].coordinate_identifier"]
    distribution_sources.source[:].markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    distribution_sources.source[:].markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].process[:].nbi_beamlets_group

    Index of the NBI beamlets group considered. Refers to the "unit/beamlets_group" array of the NBI IDS. 0 means sum over all beamlets groups.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].nbi_energy.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].nbi_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].nbi_energy.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].nbi_unit

    Index of the NBI unit considered. Refers to the "unit" array of the NBI IDS. 0 means sum over all NBI units.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].reactant_energy.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].reactant_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].reactant_energy.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].process[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].process[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].profiles_1d[:].energy

    Source term for the energy transport equation

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distribution_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distribution_sources.source[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.source[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].momentum_tor

    Source term for the toroidal momentum equation

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].particles

    Source term for the density transport equation

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm"]
    distribution_sources.source[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distribution_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distribution_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distribution_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distribution_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distribution_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    distribution_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distribution_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    distribution_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distribution_sources.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["distribution_sources.time"]
    distribution_sources.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    distributions.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.code.library[:].name

    Name of software

    • Data Type: STR_0D
    distributions.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    distributions.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["distributions.time"]
    distributions.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.code.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values", "1...N"]
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values", "1...N"]
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["distributions.distribution[:].ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].ggd[:].temperature

    Reference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_fast

    Collisional power to the fast particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_thermal

    Collisional power to the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque to the fast particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque to the thermal particle population

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].current_tor

    Toroidal current driven by the distribution

    • Units: A
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy

    Total energy in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy_fast

    Total energy of the fast particles in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].energy_fast_parallel

    Parallel energy of the fast particles in the distribution

    • Units: J
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].particles_fast_n

    Number of fast particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)

    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].particles_n

    Number of particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)

    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].global_quantities[:].source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].global_quantities[:].source[:].particles

    Particle source rate

    • Units: s^-1
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].power

    Total power of the source

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].source[:].torque_tor

    Total toroidal torque of the source

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.particles

    Source rate of thermal particles due to the thermalisation of fast particles

    • Units: s^-1
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.power

    Power input to the thermal particle population due to the thermalisation of fast particles

    • Units: W
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].thermalisation.torque

    Torque input to the thermal particle population due to the thermalisation of fast particles

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].global_quantities[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m
    • Data Type: FLT_0D
    distributions.distribution[:].gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    distributions.distribution[:].is_delta_f

    If isdeltaf=1, then the distribution represents the deviation from a Maxwellian; isdeltaf=0, then the distribution represents all particles, i.e. the full-f solution

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["distributions.distribution[:].markers[:].orbit_integrals.expressions", "distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].orbit_integrals.n_tor", "distributions.distribution[:].markers[:].orbit_integrals.m_pol", "distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["distributions.distribution[:].markers[:].orbit_integrals_instant.expressions", "distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit"]
    distributions.distribution[:].markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].markers[:].weights", "distributions.distribution[:].markers[:].coordinate_identifier"]
    distributions.distribution[:].markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    distributions.distribution[:].markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].process[:].nbi_beamlets_group

    Index of the NBI beamlets group considered. Refers to the "unit/beamlets_group" array of the NBI IDS. 0 means sum over all beamlets groups.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].nbi_energy.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].nbi_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].nbi_energy.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].process[:].nbi_unit

    Index of the NBI unit considered. Refers to the "unit" array of the NBI IDS. 0 means sum over all NBI units.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].reactant_energy.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].reactant_energy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].reactant_energy.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].process[:].type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].process[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].process[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].co_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].counter_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].fast_filter.energy

    Energy at which the fast and thermal particle populations were separated, as a function of radius

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].fast_filter.method.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].fast_filter.method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].fast_filter.method.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.energy

    Source rate of energy density within the thermal particle population due to the thermalisation of fast particles

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.momentum_tor

    Source rate of toroidal angular momentum density within the thermal particle population due to the thermalisation of fast particles

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].thermalisation.particles

    Source rate of thermal particle density due to the thermalisation of fast particles

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_1d[:].trapped.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].energy

    Source rate of energy density

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.process_index

    Index into distribution/process

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.wave_index

    Index into distribution/wave

    • Data Type: INT_0D
    distributions.distribution[:].profiles_1d[:].trapped.source[:].momentum_tor

    Source rate of toroidal angular momentum density

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.source[:].particles

    Source rate of thermal particle density

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_1d[:].trapped.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].co_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].co_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].counter_passing.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].counter_passing.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.rho_tor

    Toroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.theta_geometric

    Geometrical poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.theta_straight

    Straight field line poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].grid.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].grid.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].grid.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm"]
    distributions.distribution[:].profiles_2d[:].grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.distribution[:].profiles_2d[:].pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_fast

    Collisional power density to the fast particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_thermal

    Collisional power density to the thermal particle population

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_fast_tor

    Collisional toroidal torque density to the fast particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_thermal_tor

    Collisional toroidal torque density to the thermal particle population

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].profiles_2d[:].trapped.current_fast_tor

    Total toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.current_tor

    Total toroidal driven current density (including electron and thermal ion back-current, or drag-current)

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.density_fast

    Density of fast particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure

    Pressure (thermal+non-thermal)

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure_fast

    Pressure of fast particles

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.pressure_fast_parallel

    Pressure of fast particles in the parallel direction

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].profiles_2d[:].trapped.torque_tor_j_radial

    Toroidal torque due to radial currents

    • Units: N.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["distributions.distribution[:].profiles_2d[:].grid.r", "distributions.distribution[:].profiles_2d[:].grid.z"]
    distributions.distribution[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    distributions.distribution[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    distributions.distribution[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    distributions.distribution[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].antenna_name

    Name of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].index_in_antenna

    Index of the wave (starts at 1), separating different waves generated from a single antenna.

    • Data Type: INT_0D
    distributions.distribution[:].wave[:].type.description

    Verbose description

    • Data Type: STR_0D
    distributions.distribution[:].wave[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.distribution[:].wave[:].type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    distributions.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    distributions.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    distributions.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    distributions.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    distributions.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    distributions.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    distributions.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    distributions.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    distributions.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    distributions.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    distributions.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    distributions.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    distributions.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    distributions.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    distributions.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    distributions.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["distributions.time"]
    distributions.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    divertors.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.code.library[:].name

    Name of software

    • Data Type: STR_0D
    divertors.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    divertors.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["divertors.time"]
    divertors.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.code.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.divertor[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].current_incident.time"]
    divertors.divertor[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].identifier

    Alphanumeric identifier of divertor

    • Data Type: STR_0D
    divertors.divertor[:].name

    Name of the divertor

    • Data Type: STR_0D
    divertors.divertor[:].particle_flux_recycled_total.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].particle_flux_recycled_total.time"]
    divertors.divertor[:].particle_flux_recycled_total.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_black_body.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_black_body.time"]
    divertors.divertor[:].power_black_body.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_conducted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_conducted.time"]
    divertors.divertor[:].power_conducted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_convected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_convected.time"]
    divertors.divertor[:].power_convected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_currents.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_currents.time"]
    divertors.divertor[:].power_currents.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_incident.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_incident.time"]
    divertors.divertor[:].power_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_neutrals.time"]
    divertors.divertor[:].power_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_radiated.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_radiated.time"]
    divertors.divertor[:].power_radiated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_recombination_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_recombination_neutrals.time"]
    divertors.divertor[:].power_recombination_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_recombination_plasma.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_recombination_plasma.time"]
    divertors.divertor[:].power_recombination_plasma.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].power_thermal_extracted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].power_thermal_extracted.time"]
    divertors.divertor[:].power_thermal_extracted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].current_incident.time"]
    divertors.divertor[:].target[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].extension_r

    Target length projected on the major radius axis

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].extension_z

    Target length projected on the height axis

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].flux_expansion.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].flux_expansion.time"]
    divertors.divertor[:].target[:].flux_expansion.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].heat_flux_steady_limit_max

    Maximum steady state heat flux allowed on divertor target surface (engineering design limit)

    • Units: W.m^-2
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].identifier

    Alphanumeric identifier of target

    • Data Type: STR_0D
    divertors.divertor[:].target[:].name

    Name of the target

    • Data Type: STR_0D
    divertors.divertor[:].target[:].power_black_body.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_black_body.time"]
    divertors.divertor[:].target[:].power_black_body.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_conducted.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_conducted.time"]
    divertors.divertor[:].target[:].power_conducted.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_convected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_convected.time"]
    divertors.divertor[:].target[:].power_convected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_currents.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_currents.time"]
    divertors.divertor[:].target[:].power_currents.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_flux_peak.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_flux_peak.time"]
    divertors.divertor[:].target[:].power_flux_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_incident.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_incident.time"]
    divertors.divertor[:].target[:].power_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_incident_fraction.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_incident_fraction.time"]
    divertors.divertor[:].target[:].power_incident_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_neutrals.time"]
    divertors.divertor[:].target[:].power_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_radiated.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_radiated.time"]
    divertors.divertor[:].target[:].power_radiated.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_recombination_neutrals.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_recombination_neutrals.time"]
    divertors.divertor[:].target[:].power_recombination_neutrals.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].power_recombination_plasma.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].power_recombination_plasma.time"]
    divertors.divertor[:].target[:].power_recombination_plasma.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].t_e_target_sputtering_limit_max

    Maximum plasma temperature allowed on the divertor target to avoid excessive sputtering

    • Units: eV
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].temperature_limit_max

    Maximum surface target temperature allowed to prevent damage (melting, recrystallization, sublimation, etc...)

    • Units: K
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].tile[:].current_incident.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].current_incident.time"]
    divertors.divertor[:].target[:].tile[:].current_incident.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tile[:].identifier

    Alphanumeric identifier of tile

    • Data Type: STR_0D
    divertors.divertor[:].target[:].tile[:].name

    Name of the tile

    • Data Type: STR_0D
    divertors.divertor[:].target[:].tile[:].shunt_index

    If the tile carries a measurement shunt, index of that shunt (in the magnetics IDS shunt array)

    • Data Type: INT_0D
    divertors.divertor[:].target[:].tile[:].surface_area

    Area of the tile surface facing the plasma

    • Units: m^2
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].tile[:].surface_outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].surface_outline.r"]
    divertors.divertor[:].target[:].tile[:].surface_outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tile[:].surface_outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tile[:].surface_outline.r"]
    divertors.divertor[:].target[:].tilt_angle_pol.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tilt_angle_pol.time"]
    divertors.divertor[:].target[:].tilt_angle_pol.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].tilt_angle_tor.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].tilt_angle_tor.time"]
    divertors.divertor[:].target[:].tilt_angle_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].target[:].two_point_model[:].n_e_target

    Electron density at divertor target

    • Units: m^-3
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].sol_heat_decay_length

    Heat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].sol_heat_spreading_length

    Heat flux spreading length in SOL at equatorial mid-plane, this is the S power spreading parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031. Relevant only for attached plasmas.

    • Units: m
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].t_e_target

    Electron temperature at divertor target

    • Units: eV
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].two_point_model[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    divertors.divertor[:].target[:].wetted_area.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].target[:].wetted_area.time"]
    divertors.divertor[:].target[:].wetted_area.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.divertor[:].wetted_area.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["divertors.divertor[:].wetted_area.time"]
    divertors.divertor[:].wetted_area.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    divertors.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    divertors.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    divertors.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    divertors.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    divertors.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    divertors.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    divertors.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    divertors.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    divertors.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    divertors.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    divertors.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    divertors.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    divertors.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    divertors.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    divertors.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    divertors.midplane.description

    Verbose description

    • Data Type: STR_0D
    divertors.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    divertors.midplane.name

    Short string identifier

    • Data Type: STR_0D
    divertors.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    ec_launchers.beam[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    ec_launchers.beam[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    ec_launchers.beam[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].frequency.time"]
    ec_launchers.beam[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].identifier

    Beam identifier

    • Data Type: STR_0D
    ec_launchers.beam[:].launching_position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].launching_position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].launching_position.r_limit_max

    Major radius upper limit for the system

    • Units: m
    • Data Type: FLT_0D
    ec_launchers.beam[:].launching_position.r_limit_min

    Major radius lower limit for the system

    • Units: m
    • Data Type: FLT_0D
    ec_launchers.beam[:].launching_position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].mode

    Identifier for the main plasma wave mode excited by the EC beam. For the ordinary mode (O-mode), mode=1. For the extraordinary mode (X-mode), mode=-1

    • Data Type: INT_0D
    ec_launchers.beam[:].name

    Beam name

    • Data Type: STR_0D
    ec_launchers.beam[:].o_mode_fraction

    Fraction of EC beam power launched in ordinary (O) mode. If all power is launched in ordinary mode (O-mode), omodefraction = 1.0. If all power is launched in extraordinary mode (X-mode), omodefraction = 0.0

    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].phase.angle

    Rotation angle for the phase ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].phase.curvature

    Inverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "ec_launchers.beam[:].time"]
    ec_launchers.beam[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].power_launched.time"]
    ec_launchers.beam[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.beam[:].spot.angle

    Rotation angle for the spot ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].spot.size

    Size of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "ec_launchers.beam[:].time"]
    ec_launchers.beam[:].steering_angle_pol

    Steering angle of the EC beam in the R,Z plane (from the -R axis towards the -Z axis), anglepol=atan2(-kZ,-kR), where kZ and k_R are the Z and R components of the mean wave vector in the EC beam

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].steering_angle_tor

    Steering angle of the EC beam away from the poloidal plane that is increasing towards the positive phi axis, angletor=arcsin(kphi/k), where k_phi is the component of the wave vector in the phi direction and k is the length of the wave vector. Here the term wave vector refers to the mean wave vector in the EC beam

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ec_launchers.beam[:].time"]
    ec_launchers.beam[:].time

    Time base used for launchingposition, omode_fraction, angle, spot and phase quantities

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ec_launchers.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ec_launchers.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ec_launchers.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ec_launchers.time"]
    ec_launchers.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.code.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ec_launchers.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ec_launchers.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ec_launchers.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ec_launchers.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ec_launchers.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ec_launchers.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ec_launchers.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ec_launchers.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ec_launchers.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ec_launchers.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ec_launchers.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    ec_launchers.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.phase.angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].beam.phase.angle.time"]
    ece.channel[:].beam.phase.angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.phase.curvature.data

    Data

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "ece.channel[:].beam.phase.curvature.time"]
    ece.channel[:].beam.phase.curvature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.spot.angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].beam.spot.angle.time"]
    ece.channel[:].beam.spot.angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].beam.spot.size.data

    Data

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "ece.channel[:].beam.spot.size.time"]
    ece.channel[:].beam.spot.size.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].delta_position_suprathermal.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].delta_position_suprathermal.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].frequency.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].frequency.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].harmonic.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].harmonic.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].harmonic.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    ece.channel[:].if_bandwidth

    Full-width of the Intermediate Frequency (IF) bandpass filter

    • Units: Hz
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    ece.channel[:].optical_depth.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].optical_depth.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].optical_depth.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].time"]
    ece.channel[:].t_e_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["ece.channel[:].t_e_voltage.time"]
    ece.channel[:].t_e_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.channel[:].t_e_voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.channel[:].t_e_voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.channel[:].t_e_voltage.time"]
    ece.channel[:].time

    Timebase for the processed dynamic data of this channel (outside of the beam structure)

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ece.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ece.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ece.time"]
    ece.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.code.repository

    URL of software repository

    • Data Type: STR_0D
    ece.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ece.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ece.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ece.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ece.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ece.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ece.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ece.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ece.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ece.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ece.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ece.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ece.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ece.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ece.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ece.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ece.polarizer[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].polarization_angle

    Alignment angle of the polarizer in the (x1,x2) plane. Electric fields parallel to the polarizer angle will be reflected. The angle is defined with respect to the x1 unit vector, positive in the counter-clockwise direction when looking towards the plasma

    • Units: rad
    • Data Type: FLT_0D
    ece.polarizer[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    ece.polarizer[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    ece.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["ece.psi_normalization.time"]
    ece.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["ece.psi_normalization.time"]
    ece.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.t_e_central.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.t_e_central.rho_tor_norm

    Normalised toroidal flux coordinate of the measurement

    • Data Type: FLT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.t_e_central.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ece.t_e_central.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    ece.t_e_central.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["ece.t_e_central.time"]
    ece.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_profiles.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_profiles.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.time"]
    edge_profiles.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ggd[:].a_field_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].a_field_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].a_field_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].a_field_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].a_field_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].e_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].e_field[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].e_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].e_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.density[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].electrons.temperature[:].values", "1...N"]
    edge_profiles.ggd[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].electrons.velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].electrons.velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].z_average[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Elementary Charge Unit
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Elementary Charge Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].ion[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].ion[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].ion[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].ion[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].j_anomalous[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_anomalous[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_anomalous[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_anomalous[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_anomalous[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_heat_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_heat_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_heat_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_inertial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_inertial[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_inertial[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_inertial[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_ion_neutral_friction[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].j_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].j_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_parallel_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_parallel_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_perpendicular_viscosity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_pfirsch_schlueter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].j_total[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].j_total[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].j_total[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].n_i_total_over_n_e[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].n_i_total_over_n_e[:].values", "1...N"]
    edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].n_i_total_over_n_e[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].density[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].neutral[:].temperature[:].values", "1...N"]
    edge_profiles.ggd[:].neutral[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].velocity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].neutral[:].velocity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].neutral[:].velocity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].phi_potential[:].values", "1...N"]
    edge_profiles.ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_parallel[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_perpendicular[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].pressure_thermal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].pressure_thermal[:].values", "1...N"]
    edge_profiles.ggd[:].pressure_thermal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_thermal[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].pressure_thermal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].t_i_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].t_i_average[:].values", "1...N"]
    edge_profiles.ggd[:].t_i_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].t_i_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].t_i_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.ggd[:].zeff[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_profiles.ggd[:].zeff[:].values", "1...N"]
    edge_profiles.ggd[:].zeff[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd[:].zeff[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd[:].zeff[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.ggd_fast[:].electrons.density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.density[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: m^-3
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].electrons.temperature[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].energy_thermal[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: J
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].content[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].density[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: m^-3
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.ggd_fast[:].ion[:].temperature[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element"]
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element"]
    edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_profiles.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_profiles.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_profiles.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_profiles.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_profiles.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_profiles.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_profiles.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_profiles.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_profiles.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_profiles.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_profiles.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_profiles.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].current_parallel_inside

    Parallel current driven inside the flux surface. Cumulative surface integral of j_total

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.diamagnetic

    Diamagnetic component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.parallel

    Parallel component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.poloidal

    Poloidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.radial

    Radial component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].e_field.toroidal

    Toroidal component

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.collisionality_norm

    Collisionality normalised to the bounce frequency

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].electrons.density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.density_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].electrons.temperature_fit.measured"]
    edge_profiles.profiles_1d[:].electrons.temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].density_validity

    Indicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured

    Measured values

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed

    Value reconstructed from the fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential

    Cumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: eV
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor

    Toroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)

    • Units: rad.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average

    Average Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average_1d

    Average charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d

    Average square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].state[:].z_square_average

    Average Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured"]
    edge_profiles.profiles_1d[:].ion[:].temperature_validity

    Indicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be used

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].ion[:].velocity.diamagnetic

    Diamagnetic component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.parallel

    Parallel component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.poloidal

    Poloidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.radial

    Radial component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].velocity.toroidal

    Toroidal component

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].ion[:].z_ion_1d

    Average charge of the ion species (sum of states charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].ion[:].z_ion_square_1d

    Average square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].n_i_thermal_total

    Total ion thermal density (sum over species and charge states)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].label

    String identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].pressure

    Pressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure

    Pressure (thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal

    Pressure (thermal) associated with random motion ~average((v-average(v))^2)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].phi_potential

    Electrostatic potential, averaged on the magnetic flux surface

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_ion_total

    Total (sum over ion species) thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].q

    Safety factor

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].rotation_frequency_tor_sonic

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].t_i_average_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.measured

    Measured values

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].t_i_average_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.reconstructed

    Value reconstructed from the fit

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].t_i_average_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].t_i_average_fit.measured"]
    edge_profiles.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].grid.rho_pol_norm"]
    edge_profiles.profiles_1d[:].zeff_fit.chi_squared

    Squared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.local

    Integer flag : 1 means local measurement, 0 means line-integrated measurement

    • Data Type: INT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.measured

    Measured values

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.profiles_1d[:].zeff_fit.parameters

    List of the fit specific parameters in XML format

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.reconstructed

    Value reconstructed from the fit

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.rho_pol_norm

    Normalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.rho_tor_norm

    Normalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.source

    Path to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDS

    • Data Type: STR_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement

    Exact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.profiles_1d[:].zeff_fit.time_measurement_width

    In case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.profiles_1d[:].zeff_fit.weight

    Weight given to each measured value

    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.profiles_1d[:].zeff_fit.measured"]
    edge_profiles.statistics[:].quantity_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].quantity_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].quantity_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics value

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index

    Only if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path

    For Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3)

    • Data Type: INT_0D
    edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].value

    Value of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.statistics[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.statistics[:].time_width

    Width of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    edge_profiles.statistics[:].uq_input_2d[:].distribution.bins

    Bins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantity

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].uq_input_2d[:].distribution.probability

    Probability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantity

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_profiles.statistics[:].uq_input_2d[:].path

    Path of the quantity within the IDS, following the syntax given in the link below

    • Data Type: STR_0D
    edge_profiles.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_profiles.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["edge_profiles.time"]
    edge_profiles.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    edge_sources.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_sources.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_sources.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_sources.time"]
    edge_sources.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element"]
    edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element"]
    edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_sources.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_sources.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_sources.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_sources.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_sources.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_sources.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_sources.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_sources.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_sources.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_sources.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_sources.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_sources.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].current[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].current[:].values", "1...N"]
    edge_sources.source[:].ggd[:].current[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].current[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].current[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].electrons.energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].electrons.energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].electrons.energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].electrons.particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].electrons.particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].electrons.particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].electrons.particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values", "1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["edge_sources.source[:].ggd[:].total_ion_energy[:].values", "1...N"]
    edge_sources.source[:].ggd[:].total_ion_energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd[:].total_ion_energy[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    edge_sources.source[:].ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_sources.source[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].species.ion.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.label

    String identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].species.ion.state.z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.state.z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.ion.z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_sources.source[:].species.neutral.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.label

    String identifying neutral state

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].species.neutral.state.neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.source[:].species.neutral.state.vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_sources.source[:].species.neutral.state.vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_sources.source[:].species.type.description

    Verbose description

    • Data Type: STR_0D
    edge_sources.source[:].species.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_sources.source[:].species.type.name

    Short string identifier

    • Data Type: STR_0D
    edge_sources.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.code.library[:].name

    Name of software

    • Data Type: STR_0D
    edge_transport.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    edge_transport.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["edge_transport.time"]
    edge_transport.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element"]
    edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element"]
    edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["edge_transport.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    edge_transport.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    edge_transport.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    edge_transport.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    edge_transport.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    edge_transport.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    edge_transport.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    edge_transport.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    edge_transport.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    edge_transport.midplane.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.midplane.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.model[:].code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    edge_transport.model[:].code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    edge_transport.model[:].code.name

    Name of software used

    • Data Type: STR_0D
    edge_transport.model[:].code.output_flag.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["edge_transport.model[:].code.output_flag.time"]
    edge_transport.model[:].code.output_flag.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    edge_transport.model[:].code.repository

    URL of software repository

    • Data Type: STR_0D
    edge_transport.model[:].code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    edge_transport.model[:].flux_multiplier

    Multiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2

    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].conductivity[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].conductivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].conductivity[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].conductivity[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: ohm^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].label

    String identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic

    Diamagnetic component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic_coefficients

    Interpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel

    Parallel component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel_coefficients

    Interpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal

    Poloidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal_coefficients

    Interpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial

    Radial component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial_coefficients

    Interpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    edge_transport.model[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values", "1...N"]
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].electrons.power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].energy_flux_max[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W.m^-2
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd_fast[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: s^-1
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].power[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    edge_transport.model[:].ggd_fast[:].power_ion_total[:].value

    Scalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)

    • Units: W
    • Data Type: FLT_0D
    edge_transport.model[:].ggd_fast[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    edge_transport.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    edge_transport.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    edge_transport.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    edge_transport.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    em_coupling.active_coils

    List of URIs of the active coils considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_active.coil"]
    em_coupling.b_field_pol_probes

    List of URIs of the poloidal field probes considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["magnetics.b_field_pol_probe"]
    em_coupling.b_field_pol_probes_active

    Poloidal field coupling from active coils to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["magnetics.b_field_pol_probe", "em_coupling.active_coils"]
    em_coupling.b_field_pol_probes_passive

    Poloidal field coupling from passive loops to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.b_field_pol_probes", "em_coupling.passive_loops"]
    em_coupling.b_field_pol_probes_plasma

    Poloidal field coupling from plasma elements to poloidal field probes

    • Units: T/A
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.b_field_pol_probes", "em_coupling.plasma_elements"]
    em_coupling.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.code.library[:].name

    Name of software

    • Data Type: STR_0D
    em_coupling.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    em_coupling.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["em_coupling.time"]
    em_coupling.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.code.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].columns_uri

    List of URIs corresponding to the columns (2nd dimension) of the coupling matrix. See examples above (rows_uri)

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.coupling_matrix[:].data

    Coupling matrix

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.coupling_matrix[:].rows_uri", "em_coupling.coupling_matrix[:].columns_uri"]
    em_coupling.coupling_matrix[:].name

    Name of this coupling matrix

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].quantity.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].quantity.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.coupling_matrix[:].quantity.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.coupling_matrix[:].rows_uri

    List of URIs corresponding to the rows (1st dimension) of the coupling matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector, it is sufficient to give a insgle uri, the one of the vector with the impliicit notation (:), e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.flux_loops

    List of URIs of the flux loops considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["magnetics.flux_loop"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element"]
    em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["em_coupling.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    em_coupling.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    em_coupling.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    em_coupling.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    em_coupling.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    em_coupling.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    em_coupling.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    em_coupling.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    em_coupling.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    em_coupling.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    em_coupling.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    em_coupling.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    em_coupling.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    em_coupling.mutual_active_active

    Mutual inductance coupling from active coils to active coils

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.active_coils", "em_coupling.active_coils"]
    em_coupling.mutual_loops_active

    Mutual inductance coupling from active coils to flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.active_coils"]
    em_coupling.mutual_loops_passive

    Mutual inductance coupling from passive loops to flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.passive_loops"]
    em_coupling.mutual_loops_plasma

    Mutual inductance from plasma elements to poloidal flux loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.flux_loops", "em_coupling.plasma_elements"]
    em_coupling.mutual_passive_active

    Mutual inductance coupling from active coils to passive loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.passive_loops", "em_coupling.active_coils"]
    em_coupling.mutual_passive_passive

    Mutual inductance coupling from passive loops to passive loops

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.passive_loops", "em_coupling.passive_loops"]
    em_coupling.mutual_plasma_active

    Mutual inductance coupling from active coils to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.active_coils"]
    em_coupling.mutual_plasma_passive

    Mutual inductance coupling from passive loops to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.passive_loops"]
    em_coupling.mutual_plasma_plasma

    Mutual inductance coupling from plasma elements to plasma elements

    • Units: H
    • Data Type: FLT_2D
    • Coordinates: ["em_coupling.plasma_elements", "em_coupling.plasma_elements"]
    em_coupling.passive_loops

    List of URIs of the passive loops considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_passive.loop"]
    em_coupling.plasma_elements

    List of URIs of the plasma elements considered in the IDS

    • Data Type: STR_1D
    • Coordinates: ["pf_plasma.element"]
    em_coupling.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.code.library[:].name

    Name of software

    • Data Type: STR_0D
    equilibrium.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    equilibrium.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["equilibrium.time"]
    equilibrium.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.code.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["equilibrium.grids_ggd[:].grid[:].grid_subset[:].element", "1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    equilibrium.grids_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    equilibrium.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    equilibrium.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    equilibrium.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    equilibrium.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    equilibrium.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    equilibrium.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    equilibrium.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    equilibrium.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    equilibrium.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    equilibrium.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary.active_limiter_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.active_limiter_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation

    Elongation of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation_lower

    Elongation (lower half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.elongation_upper

    Elongation (upper half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.minor_radius

    Minor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary.outline.r"]
    equilibrium.time_slice[:].boundary.ovality

    Ovality of the plasma boundary [MXH c1]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.psi

    Value of the poloidal flux at which the boundary is taken

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.psi_norm

    Value of the normalised poloidal flux at which the boundary is taken (typically 99.x %), the flux being normalised to its value at the separatrix

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness

    Squareness of the plasma boundary [MXH -s2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_lower_inner

    Lower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_lower_outer

    Lower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_upper_inner

    Upper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.squareness_upper_outer

    Upper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.tilt

    Tilt of the plasma boundary [MXH c0]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity

    Triangularity of the plasma boundary [MXH sin(s1)]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity_lower

    Lower triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.triangularity_upper

    Upper triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.twist

    Twist of the plasma boundary [MXH c2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.type

    0 (limiter) or 1 (diverted)

    • Data Type: INT_0D
    equilibrium.time_slice[:].boundary.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.distance_inner_outer

    Distance between the inner and outer separatrices, in the major radius direction, at the plasma outboard and at the height corresponding to the maximum R for the inner separatrix.

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary_secondary_separatrix.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r"]
    equilibrium.time_slice[:].boundary_secondary_separatrix.psi

    Value of the poloidal flux at the separatrix

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_secondary_separatrix.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.active_limiter_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.active_limiter_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.distance

    Distance to the plasma boundary

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.closest_wall_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.dr_dz_zero_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.dr_dz_zero_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation

    Elongation of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation_lower

    Elongation (lower half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.elongation_upper

    Elongation (upper half w.r.t. geometric axis) of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].angle

    Angle measured clockwise from radial cylindrical vector (grad R) to gap vector (pointing away from reference point)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].identifier

    Identifier of the gap

    • Data Type: STR_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].name

    Name of the gap

    • Data Type: STR_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].r

    Major radius of the reference point

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].value

    Value of the gap, i.e. distance between the reference point and the separatrix along the gap direction

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.gap[:].z

    Height of the reference point

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.minor_radius

    Minor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].boundary_separatrix.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].boundary_separatrix.outline.r"]
    equilibrium.time_slice[:].boundary_separatrix.psi

    Value of the poloidal flux at the separatrix

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_lower_inner

    Lower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_lower_outer

    Lower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_upper_inner

    Upper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.squareness_upper_outer

    Upper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.strike_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.strike_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity

    Triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_inner

    Inner triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_lower

    Lower triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_minor

    Minor triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_outer

    Outer triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.triangularity_upper

    Upper triangularity of the plasma boundary

    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.type

    0 (limiter) or 1 (diverted)

    • Data Type: INT_0D
    equilibrium.time_slice[:].boundary_separatrix.x_point[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].boundary_separatrix.x_point[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.measured

    Measured value

    • Units: T.m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T.m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.bpol_probe[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.chi_squared_reduced

    Sum of the chi_squared of all constraints used for the equilibrium reconstruction, divided by the number of degrees of freedom of the identification model

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.constraints_n

    Number of constraints used (i.e. having a non-zero weight)

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.measured

    Measured value

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.diamagnetic_flux.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].measured

    Measured value

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.faraday_angle[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].measured

    Measured value

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.flux_loop[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.freedom_degrees_n

    Number of degrees of freedom of the identification model

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.ip.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.ip.measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.ip.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.ip.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_r.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.measured

    Measured value

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].measured

    Measured value

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_parallel[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].measured

    Measured value

    • Units: A.m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.j_tor[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.j_tor[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].measured

    Measured value

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.n_e[:].measured

    Measured value

    • Units: m^-3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.n_e[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].measured

    Measured value

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.n_e_line[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pf_current[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_current[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].measured

    Measured value

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pf_passive_current[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pressure[:].measured

    Measured value

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pressure[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].measured

    Measured value

    • Units: Pa
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.pressure_rotational[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].chi_squared

    Squared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.q[:].measured

    Measured value

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].reconstructed

    Value calculated from the reconstructed equilibrium

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.q[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.q[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_r

    Squared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_z

    Squared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_measured.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_measured.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.strike_point[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.strike_point[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].chi_squared_r

    Squared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].chi_squared_z

    Squared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement error

    • Units: m^-2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].exact

    Integer flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fit

    • Data Type: INT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_measured.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_measured.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.z

    Height

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].source

    Path to the source data for this measurement in the IMAS data dictionary

    • Data Type: STR_0D
    equilibrium.time_slice[:].constraints.x_point[:].time_measurement

    Exact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been used

    • Units: s
    • Data Type: FLT_0D
    equilibrium.time_slice[:].constraints.x_point[:].weight

    Weight given to the measurement

    • Data Type: FLT_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.grad_shafranov_deviation_value

    Value of the residual deviation between the left and right hand side of the Grad Shafranov equation, evaluated as per gradshafranovdeviation_expression

    • Units: mixed
    • Data Type: FLT_0D
    equilibrium.time_slice[:].convergence.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.result.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].convergence.result.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].convergence.result.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2", "1...3", "1...3"]
    equilibrium.time_slice[:].coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2", "1...3", "1...3"]
    equilibrium.time_slice[:].coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].coordinate_system.grid.dim1", "equilibrium.time_slice[:].coordinate_system.grid.dim2"]
    equilibrium.time_slice[:].ggd[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_r[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_tor[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].b_field_z[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].j_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].j_parallel[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].j_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].j_tor[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].j_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].j_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].phi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].phi[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].phi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].phi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].phi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].psi[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].r[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].theta[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].theta[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].theta[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].theta[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].theta[:].values

    One scalar value is provided per element in the grid subset.

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].ggd[:].z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].ggd[:].z[:].values", "1...N"]
    equilibrium.time_slice[:].ggd[:].z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    equilibrium.time_slice[:].ggd[:].z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].global_quantities.area

    Area of the LCFS poloidal cross section

    • Units: m^2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_normal

    Normalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_pol

    Poloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.beta_tor

    Toroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.r

    Major radius of the current center, defined as integral over the poloidal cross section of (j_torrdS) / Ip

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.velocity_z

    Vertical velocity of the current center

    • Units: m.s^-1
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.current_centre.z

    Height of the current center, defined as integral over the poloidal cross section of (j_torzdS) / Ip

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.energy_mhd

    Plasma energy content = 3/2 * int(p,dV) with p being the total pressure (thermal + fast particles) [J]. Time-dependent; Scalar

    • Units: J
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.ip

    Plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Units: A
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.length_pol

    Poloidal length of the magnetic surface

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.li_3

    Internal inductance

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.b_field_tor

    Total toroidal magnetic field at the magnetic axis

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.r

    Major radius of the magnetic axis

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.magnetic_axis.z

    Height of the magnetic axis

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.plasma_inductance

    Plasma inductance 2 Emagnetic/Ip^2, where Emagnetic = 1/2 * int(psi.j_tor.dS) (integral over the plasma poloidal cross-section)

    • Units: H
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.plasma_resistance

    Plasma resistance = int(e_field.j.dV) / Ip^2

    • Units: ohm
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_axis

    Poloidal flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_boundary

    Poloidal flux at the selected plasma boundary

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.psi_external_average

    Average (over the plasma poloidal cross section) plasma poloidal magnetic flux produced by all external circuits (CS and PF coils, eddy currents, VS in-vessel coils), given by the following formula : int(psiexternal.jtor.dS) / Ip

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_95

    q at the 95% poloidal flux surface (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_axis

    q at the magnetic axis

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.psi

    Minimum q position in poloidal flux

    • Units: Wb
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.psi_norm

    Minimum q position in normalised poloidal flux

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.rho_tor_norm

    Minimum q position in normalised toroidal flux coordinate

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.q_min.value

    Minimum q value

    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.rho_tor_boundary

    Toroidal flux coordinate at the selected plasma boundary

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.v_external

    External voltage, i.e. time derivative of psiexternalaverage (with a minus sign : - dpsiexternalaverage/dtime)

    • Units: V
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    equilibrium.time_slice[:].global_quantities.volume

    Total plasma volume

    • Units: m^3
    • Data Type: FLT_0D
    equilibrium.time_slice[:].profiles_1d.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_average

    Flux surface averaged modulus of B (always positive, irrespective of the sign convention for the B-field direction).

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_max

    Maximum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.b_field_min

    Minimum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.beta_pol

    Poloidal beta profile. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.darea_dpsi

    Radial derivative of the cross-sectional area of the flux surface with respect to psi

    • Units: m^2.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.darea_drho_tor

    Radial derivative of the cross-sectional area of the flux surface with respect to rho_tor

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dpressure_dpsi

    Derivative of pressure w.r.t. psi

    • Units: Pa.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dpsi_drho_tor

    Derivative of Psi with respect to Rho_Tor

    • Units: Wb/m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dvolume_dpsi

    Radial derivative of the volume enclosed in the flux surface with respect to Psi

    • Units: m^3.Wb^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.dvolume_drho_tor

    Radial derivative of the volume enclosed in the flux surface with respect to Rho_Tor

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.elongation

    Elongation

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.f

    Diamagnetic function (F=R B_Phi)

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.f_df_dpsi

    Derivative of F w.r.t. Psi, multiplied with F

    • Units: T^2.m^2/Wb
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.fsa_bp

    Flux surface averaged Bp

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.geometric_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.geometric_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm1

    Flux surface averaged 1/R^2

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm10

    Flux surface averaged R^2

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm2

    Flux surface averaged |gradrhotor|^2/R^2

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm3

    Flux surface averaged |gradrhotor|^2

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm4

    Flux surface averaged 1/B^2

    • Units: T^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm5

    Flux surface averaged B^2

    • Units: T^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm6

    Flux surface averaged |gradrhotor|^2/B^2

    • Units: T^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm7

    Flux surface averaged |gradrhotor|

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm8

    Flux surface averaged R

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.gm9

    Flux surface averaged 1/R

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.j_parallel

    Flux surface averaged approximation to parallel current density = average(j.B) / B0, where B0 = /vacuumtoroidalfield/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.j_tor

    Flux surface averaged toroidal current density = average(j_tor/R) / average(1/R)

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.mass_density

    Mass density

    • Units: kg.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.psi

    Poloidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_1d.psi_norm

    Normalised poloidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.q

    Safety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.r_inboard

    Radial coordinate (major radius) on the inboard side of the magnetic axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.r_outboard

    Radial coordinate (major radius) on the outboard side of the magnetic axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_tor

    Toroidal flux coordinate = sqrt(phi/(pi*b0)), where the toroidal flux, phi, corresponds to timeslice/profiles1d/phi, the toroidal magnetic field, b0, corresponds to vacuumtoroidalfield/b0 and pi can be found in the IMAS constants

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.rho_volume_norm

    Normalised square root of enclosed volume (radial coordinate). The normalizing value is the enclosed volume at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_lower_inner

    Lower inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_lower_outer

    Lower outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_upper_inner

    Upper inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.squareness_upper_outer

    Upper outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.trapped_fraction

    Trapped particle fraction

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.triangularity_lower

    Lower triangularity w.r.t. magnetic axis

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.triangularity_upper

    Upper triangularity w.r.t. magnetic axis

    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_1d.volume

    Volume enclosed in the flux surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time_slice[:].profiles_1d.psi"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_r

    R component of the poloidal magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_tor

    Toroidal component of the magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].b_field_z

    Z component of the poloidal magnetic field

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    equilibrium.time_slice[:].profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].j_parallel

    Defined as (j.B)/B0 where j and B are the current density and magnetic field vectors and B0 is the (signed) vacuum toroidal magnetic field strength at the geometric reference point (R0,Z0). It is formally not the component of the plasma current density parallel to the magnetic field

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].j_tor

    Toroidal plasma current density

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].psi

    Values of the poloidal flux at the grid in the poloidal plane

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].theta

    Values of the poloidal angle on the grid

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].profiles_2d[:].type.description

    Verbose description

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    equilibrium.time_slice[:].profiles_2d[:].type.name

    Short string identifier

    • Data Type: STR_0D
    equilibrium.time_slice[:].profiles_2d[:].z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["equilibrium.time_slice[:].profiles_2d[:].grid.dim1", "equilibrium.time_slice[:].profiles_2d[:].grid.dim2"]
    equilibrium.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    equilibrium.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["equilibrium.time"]
    equilibrium.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    ferritic.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ferritic.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ferritic.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ferritic.time"]
    ferritic.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.code.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element"]
    ferritic.grid_ggd.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].dimension

    Space dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].dimension

    Dimension of the object

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element"]
    ferritic.grid_ggd.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["ferritic.grid_ggd.grid_subset[:].element", "1...N", "1...N"]
    ferritic.grid_ggd.identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ferritic.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ferritic.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ferritic.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ferritic.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ferritic.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ferritic.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ferritic.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ferritic.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ferritic.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ferritic.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ferritic.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ferritic.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ferritic.object[:].axisymmetric[:].annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].arcs_of_circle.r"]
    ferritic.object[:].axisymmetric[:].arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].axisymmetric[:].arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].arcs_of_circle.r"]
    ferritic.object[:].axisymmetric[:].geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    ferritic.object[:].axisymmetric[:].oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].axisymmetric[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].axisymmetric[:].outline.r"]
    ferritic.object[:].axisymmetric[:].rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].axisymmetric[:].thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    ferritic.object[:].centroid.x

    List of X coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.object[:].centroid.y

    List of Y coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].centroid.z

    List of Z coordinates

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].ggd_object_index

    Index of GGD volumic object corresponding to each element. Refers to the array /gridggd/space(1)/objectsper_dimension(4)/object

    • Data Type: INT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].permeability_table_index

    Index of permeability table to be used for each element. If not allocated or if an element is equal to EMPTYINT, use the sibling saturated relative permeability instead ../relativepermeability, for that element

    • Data Type: INT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].saturated_relative_permeability

    Saturated relative magnetic permeability of each element

    • Units: H.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_r

    R component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_tor

    Toroidal component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].b_field_z

    Z component of the magnetic field at each centroid

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_r

    R component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_tor

    Toroidal component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].magnetic_moment_z

    Z component of the magnetic moment of each element

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.object[:].time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ferritic.object[:].volume

    Volume of each element of this object

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["ferritic.object[:].centroid.x"]
    ferritic.permeability_table[:].b_field

    Array of magnetic field values, for each of which the relative permeability is given

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ferritic.permeability_table[:].description

    Description of this table

    • Data Type: STR_0D
    ferritic.permeability_table[:].name

    Name of this table

    • Data Type: STR_0D
    ferritic.permeability_table[:].relative_permeability

    Relative permeability as a function of the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["ferritic.permeability_table[:].b_field"]
    ferritic.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.b_field_z.data

    Data

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "focs.b_field_z.time"]
    focs.b_field_z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.b_field_z.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    focs.b_field_z.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["focs.b_field_z.time"]
    focs.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.code.library[:].name

    Name of software

    • Data Type: STR_0D
    focs.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    focs.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["focs.time"]
    focs.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.code.repository

    URL of software repository

    • Data Type: STR_0D
    focs.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["focs.current.time"]
    focs.current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    focs.current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["focs.current.time"]
    focs.fibre_length

    Spun fibre length on the vacuum vessel

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.beat_length

    Linear beat length

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.id

    ID of the fibre, e.g. commercial reference

    • Data Type: STR_0D
    focs.fibre_properties.spun

    Spun period

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.spun_initial_azimuth

    Spun fibre initial azimuth

    • Units: rad
    • Data Type: FLT_0D
    focs.fibre_properties.twist

    Twist period

    • Units: m
    • Data Type: FLT_0D
    focs.fibre_properties.verdet_constant

    Verdet constant

    • Units: rad.T^-1.m^-1
    • Data Type: FLT_0D
    focs.id

    ID of the FOCS

    • Data Type: STR_0D
    focs.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    focs.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    focs.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    focs.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    focs.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    focs.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    focs.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    focs.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    focs.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    focs.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    focs.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    focs.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    focs.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    focs.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    focs.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    focs.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    focs.name

    Name of the FOCS

    • Data Type: STR_0D
    focs.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["focs.outline.r"]
    focs.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    focs.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["focs.outline.r"]
    focs.stokes_initial.s0

    S0 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s1

    S1 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s2

    S2 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_initial.s3

    S3 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s0

    S0 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s1

    S1 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s2

    S2 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].s3

    S3 component of the unit Stokes vector

    • Data Type: FLT_0D
    focs.stokes_output[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    focs.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gas_injection.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gas_injection.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gas_injection.time"]
    gas_injection.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.code.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gas_injection.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gas_injection.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gas_injection.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gas_injection.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gas_injection.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gas_injection.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_injection.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_injection.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gas_injection.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gas_injection.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gas_injection.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].exit_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.pipe[:].flow_rate.time"]
    gas_injection.pipe[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.pipe[:].identifier

    ID of the injection pipe

    • Data Type: STR_0D
    gas_injection.pipe[:].length

    Pipe length

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].name

    Name of the injection pipe

    • Data Type: STR_0D
    gas_injection.pipe[:].second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    gas_injection.pipe[:].second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_injection.pipe[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    gas_injection.pipe[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    gas_injection.pipe[:].valve_indices

    Indices (from the ../../valve array of structure) of the valve(s) that are feeding this pipe

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    gas_injection.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].electron_rate.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].electron_rate.time"]
    gas_injection.valve[:].electron_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].flow_rate.time"]
    gas_injection.valve[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].flow_rate_max

    Maximum flow rate of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_0D
    gas_injection.valve[:].flow_rate_min

    Minimum flow rate of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_0D
    gas_injection.valve[:].identifier

    ID of the valve

    • Data Type: STR_0D
    gas_injection.valve[:].name

    Name of the valve

    • Data Type: STR_0D
    gas_injection.valve[:].pipe_indices

    Indices (from the ../../pipe array of structure) of the pipe(s) that are fed by this valve

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].response_curve.flow_rate

    Flow rate at the exit of the valve

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].response_curve.voltage"]
    gas_injection.valve[:].response_curve.voltage

    Voltage applied to open the valve

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_injection.valve[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_injection.valve[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    gas_injection.valve[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    gas_injection.valve[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["gas_injection.valve[:].voltage.time"]
    gas_injection.valve[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gas_pumping.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gas_pumping.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gas_pumping.time"]
    gas_pumping.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.code.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.duct[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_pumping.duct[:].flow_rate.time"]
    gas_pumping.duct[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.duct[:].identifier

    ID of the pumping duct

    • Data Type: STR_0D
    gas_pumping.duct[:].name

    Name of the pumping duct

    • Data Type: STR_0D
    gas_pumping.duct[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    gas_pumping.duct[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    gas_pumping.duct[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    gas_pumping.duct[:].species[:].flow_rate.data

    Data

    • Units: Pa.m^3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["gas_pumping.duct[:].species[:].flow_rate.time"]
    gas_pumping.duct[:].species[:].flow_rate.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gas_pumping.duct[:].species[:].label

    String identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)

    • Data Type: STR_0D
    gas_pumping.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gas_pumping.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gas_pumping.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gas_pumping.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gas_pumping.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gas_pumping.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gas_pumping.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gas_pumping.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gas_pumping.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gas_pumping.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gas_pumping.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gas_pumping.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].name

    Name of software

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    gyrokinetics_local.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["gyrokinetics_local.time"]
    gyrokinetics_local.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.code.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.collisions.collisionality_norm

    Normalised collisionality between two species

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.species"]
    gyrokinetics_local.flux_surface.b_field_tor_sign

    Sign of the toroidal magnetic field

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dc_dr_minor_norm

    Derivative of the 'c' shape coefficients with respect to rminornorm

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.flux_surface.shape_coefficients_c"]
    gyrokinetics_local.flux_surface.delongation_dr_minor_norm

    Derivative of the elongation with respect to rminornorm

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dgeometric_axis_r_dr_minor

    Derivative of the major radius of the surface geometric axis with respect to r_minor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.dgeometric_axis_z_dr_minor

    Derivative of the height of the surface geometric axis with respect to r_minor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.ds_dr_minor_norm

    Derivative of the 's' shape coefficients with respect to rminornorm

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.flux_surface.shape_coefficients_s"]
    gyrokinetics_local.flux_surface.elongation

    Elongation

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.ip_sign

    Sign of the plasma current

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.magnetic_shear_r_minor

    Magnetic shear, defined as rminornorm/q . dq/drminornorm (different definition from the equilibrium IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.pressure_gradient_norm

    Normalised pressure gradient (derivative with respect to rminornorm)

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.q

    Safety factor

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.r_minor_norm

    Normalised minor radius of the flux surface of interest = 1/2 * (max(R) - min(R))/L_ref

    • Data Type: FLT_0D
    gyrokinetics_local.flux_surface.shape_coefficients_c

    'c' coefficients in the formula defining the shape of the flux surface

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.flux_surface.shape_coefficients_s

    's' coefficients in the formula defining the shape of the flux surface

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    gyrokinetics_local.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    gyrokinetics_local.linear.wavevector[:].binormal_wavevector_norm

    Normalised binormal component of the wavevector

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol

    Poloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_parity

    Parity of the perturbed parallel vector potential with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_weight

    Amplitude of the perturbed parallel vector potential normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_parity

    Parity of the perturbed parallel magnetic field with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_weight

    Amplitude of the perturbed parallel magnetic field normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_parity

    Parity of the perturbed electrostatic potential with respect to theta = 0 (poloidal angle)

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_weight

    Amplitude of the perturbed electrostatic potential normalised to the sum of amplitudes of all perturbed fields

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].frequency_norm

    Frequency

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_norm

    Growth rate

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_tolerance

    Relative tolerance on the growth rate (convergence of the simulation)

    • Data Type: FLT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].initial_value_run

    Flag = 1 if this is an initial value run, 0 for an eigenvalue run

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.density

    Normalised density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.heat_flux_parallel

    Normalised parallel heat flux (integral of 0.5 * m * v_par * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.j_parallel

    Normalised parallel current density

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_parallel

    Normalised parallel temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_perpendicular

    Normalised perpendicular temperature

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_parallel_energy_perpendicular

    Normalised moment (integral over 0.5 * m * vpar * vperp^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_perpendicular_square_energy

    Normalised moment (integral over 0.5 * m * v_perp^2 * v^2)

    • Data Type: CPX_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol", "gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm"]
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].poloidal_turns

    Number of poloidal turns considered in the flux-tube simulation

    • Data Type: INT_0D
    gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm

    Normalised time of the gyrokinetic simulation

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.linear.wavevector[:].radial_wavevector_norm

    Normalised radial component of the wavevector

    • Data Type: FLT_0D
    gyrokinetics_local.model.adiabatic_electrons

    Flag = 1 if electrons are adiabatic, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_energy_conservation

    Flag = 1 if the collision operator conserves energy, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_finite_larmor_radius

    Flag = 1 if finite larmor radius effects are retained in the collision operator, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_momentum_conservation

    Flag = 1 if the collision operator conserves momentum, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.collisions_pitch_only

    Flag = 1 if only pitch-angle scattering is retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_a_field_parallel

    Flag = 1 if fluctuations of the parallel vector potential are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_b_field_parallel

    Flag = 1 if fluctuations of the parallel magnetic field are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_centrifugal_effects

    Flag = 1 if centrifugal effects are retained, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_coriolis_drift

    Flag = 1 if Coriolis drift is included, 0 otherwise

    • Data Type: INT_0D
    gyrokinetics_local.model.include_full_curvature_drift

    Flag = 1 if all contributions to the curvature drift are included (including betaprime), 0 otherwise. Neglecting the betaprime contribution (Flag=0) is only recommended together with the neglect of parallel magnetic field fluctuations

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.angle_pol

    Poloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.binormal_wavevector_norm

    Array of normalised binormal wavevectors

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    gyrokinetics_local.non_linear.fields_4d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_4d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_4d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_4D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_1d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fields_intensity_3d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_intensity_3d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_intensity_3d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fields_zonal_2d.a_field_parallel_perturbed_norm

    Normalised perturbed parallel vector potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_zonal_2d.b_field_parallel_perturbed_norm

    Normalised perturbed parallel magnetic field

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fields_zonal_2d.phi_potential_perturbed_norm

    Normalised perturbed electrostatic potential

    • Data Type: CPX_2D
    • Coordinates: ["gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_2D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_3D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_4D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised energy flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_phi_potential

    Contribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_phi_potential

    Contribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_a_field_parallel

    Contribution of the perturbed parallel electromagnetic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_b_field_parallel

    Contribution of the perturbed parallel magnetic field to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_phi_potential

    Contribution of the perturbed electrostatic potential to the normalised particle flux

    • Data Type: FLT_5D
    • Coordinates: ["gyrokinetics_local.species", "gyrokinetics_local.non_linear.binormal_wavevector_norm", "gyrokinetics_local.non_linear.radial_wavevector_norm", "gyrokinetics_local.non_linear.angle_pol", "gyrokinetics_local.non_linear.time_norm"]
    gyrokinetics_local.non_linear.quasi_linear

    Flag = 1 if the non-linear fluxes are in fact calculated by a quasi-linear model, 0 if non-linear

    • Data Type: INT_0D
    gyrokinetics_local.non_linear.radial_wavevector_norm

    Array of normalised radial wavevectors

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.non_linear.time_interval_norm

    Normalised time interval used to average fluxes in non-linear runs

    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    gyrokinetics_local.non_linear.time_norm

    Normalised time of the gyrokinetic simulation

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.normalizing_quantities.b_field_tor

    Toroidal magnetic field at major radius r

    • Units: T
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.n_e

    Electron density at outboard equatorial midplane of the flux surface (angle_pol = 0)

    • Units: m^-3
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.r

    Major radius of the flux surface of interest, defined as (min(R)+max(R))/2

    • Units: m
    • Data Type: FLT_0D
    gyrokinetics_local.normalizing_quantities.t_e

    Electron temperature at outboard equatorial midplane of the flux surface (angle_pol = 0)

    • Units: eV
    • Data Type: FLT_0D
    gyrokinetics_local.species[:].charge_norm

    Normalised charge

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].density_log_gradient_norm

    Normalised logarithmic gradient (with respect to rminornorm) of the density

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].density_norm

    Normalised density

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].mass_norm

    Normalised mass

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].potential_energy_gradient_norm

    Effective potential energy determining the poloidal variation of the species background density

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species_all.angle_pol"]
    gyrokinetics_local.species[:].potential_energy_norm

    Normalised gradient (with respect to rminornorm) of the effective potential energy

    • Data Type: FLT_1D
    • Coordinates: ["gyrokinetics_local.species_all.angle_pol"]
    gyrokinetics_local.species[:].temperature_log_gradient_norm

    Normalised logarithmic gradient (with respect to rminornorm) of the temperature

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].temperature_norm

    Normalised temperature

    • Data Type: FLT_0D
    gyrokinetics_local.species[:].velocity_tor_gradient_norm

    Normalised gradient (with respect to rminornorm) of the toroidal velocity

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.angle_pol

    Poloidal angle grid, from -pi to pi, on which the species dependent effective potential energy (which determines the poloidal variation of the density) is expressed. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    gyrokinetics_local.species_all.beta_reference

    Reference plasma beta (see detailed documentation at the root of the IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.debye_length_norm

    Debye length computed from the reference quantities (see detailed documentation at the root of the IDS)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.shearing_rate_norm

    Normalised ExB shearing rate (for non-linear runs only)

    • Data Type: FLT_0D
    gyrokinetics_local.species_all.velocity_tor_norm

    Normalised toroidal velocity of species (all species are assumed to have a purely toroidal velocity with a common toroidal angular frequency)

    • Data Type: FLT_0D
    gyrokinetics_local.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    hard_x_rays.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].aperture[:].outline.x1"]
    hard_x_rays.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    hard_x_rays.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].detector.outline.x1"]
    hard_x_rays.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].energy_band[:].energies"]
    hard_x_rays.channel[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.channel[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    hard_x_rays.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].filter_window[:].outline.x1"]
    hard_x_rays.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.channel[:].filter_window[:].wavelengths"]
    hard_x_rays.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    hard_x_rays.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    hard_x_rays.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    hard_x_rays.channel[:].radiance.data

    Data

    • Units: (photons).s^-1.m^-2.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "hard_x_rays.channel[:].radiance.time"]
    hard_x_rays.channel[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.channel[:].radiance.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    hard_x_rays.channel[:].radiance.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.channel[:].radiance.time"]
    hard_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    hard_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    hard_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.time"]
    hard_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.emissivity_profile_1d[:].emissivity

    Radial profile of the plasma emissivity in this energy band

    • Units: (photons).m^-3.str^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].rho_tor_norm", "hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].half_width_external

    External (towards separatrix) half width of the emissivity peak (in normalised toroidal flux)

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].half_width_internal

    Internal (towards magnetic axis) half width of the emissivity peak (in normalised toroidal flux)

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.emissivity_profile_1d[:].peak_position

    Normalised toroidal flux coordinate position at which the emissivity peaks

    • Data Type: FLT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.emissivity_profile_1d[:].rho_tor_norm

    Normalised toroidal flux coordinate grid

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.emissivity_profile_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    hard_x_rays.emissivity_profile_1d[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    hard_x_rays.emissivity_profile_1d[:].validity_timed

    Indicator of the validity of the emissivity profile data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["hard_x_rays.emissivity_profile_1d[:].time"]
    hard_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    hard_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    hard_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    hard_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    hard_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    hard_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    hard_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    hard_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    hard_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    hard_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    hard_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    hard_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    hard_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.coupling

    Coupling efficiency of launched microwave power to the plasma

    • Data Type: FLT_0D
    ic_antennas.antenna[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    ic_antennas.antenna[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].frequency.time"]
    ic_antennas.antenna[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].identifier

    Identifier of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].coupling_resistance.data

    Data

    • Units: ohm
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].coupling_resistance.time"]
    ic_antennas.antenna[:].module[:].coupling_resistance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].amplitude.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].current[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].current[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].current[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].current[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].current[:].phase.time"]
    ic_antennas.antenna[:].module[:].current[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].current[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].current[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].current[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].frequency.time"]
    ic_antennas.antenna[:].module[:].frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].identifier

    Identifier of the module

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].capacitance.data

    Data

    • Units: F
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time"]
    ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].matching_element[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].matching_element[:].phase.time"]
    ic_antennas.antenna[:].module[:].matching_element[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].matching_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].matching_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ic_antennas.antenna[:].module[:].matching_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].name

    Name of the module

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].phase_forward.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].phase_forward.time"]
    ic_antennas.antenna[:].module[:].phase_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].phase_reflected.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].phase_reflected.time"]
    ic_antennas.antenna[:].module[:].phase_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_forward.time"]
    ic_antennas.antenna[:].module[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_launched.time"]
    ic_antennas.antenna[:].module[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].power_reflected.time"]
    ic_antennas.antenna[:].module[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].amplitude.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].pressure[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].pressure[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].pressure[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].pressure[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].pressure[:].phase.time"]
    ic_antennas.antenna[:].module[:].pressure[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].pressure[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].pressure[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].pressure[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].current.time"]
    ic_antennas.antenna[:].module[:].strap[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].distance_to_conductor

    Distance to conducting wall or other conductor behind the antenna strap

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].strap[:].outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].outline.r"]
    ic_antennas.antenna[:].module[:].strap[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].strap[:].phase.time"]
    ic_antennas.antenna[:].module[:].strap[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].strap[:].width_tor

    Width of strap in the toroidal direction

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].voltage[:].amplitude.time"]
    ic_antennas.antenna[:].module[:].voltage[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].voltage[:].identifier

    Identifier

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].voltage[:].name

    Name

    • Data Type: STR_0D
    ic_antennas.antenna[:].module[:].voltage[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].module[:].voltage[:].phase.time"]
    ic_antennas.antenna[:].module[:].voltage[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].module[:].voltage[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].module[:].voltage[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.antenna[:].name

    Name of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    ic_antennas.antenna[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_forward.time"]
    ic_antennas.antenna[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_launched.time"]
    ic_antennas.antenna[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.antenna[:].power_reflected.time"]
    ic_antennas.antenna[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].m_pol

    Poloidal mode numbers, used to describe the spectrum of the antenna current. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/z

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].n_tor

    Toroidal mode numbers, used to describe the spectrum of the antenna current. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    ic_antennas.antenna[:].surface_current[:].spectrum

    Spectrum of the total surface current on the antenna strap and passive components expressed in poloidal and toroidal modes

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["ic_antennas.antenna[:].surface_current[:].m_pol", "ic_antennas.antenna[:].surface_current[:].n_tor"]
    ic_antennas.antenna[:].surface_current[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ic_antennas.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ic_antennas.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ic_antennas.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ic_antennas.time"]
    ic_antennas.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.code.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ic_antennas.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ic_antennas.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ic_antennas.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ic_antennas.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ic_antennas.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ic_antennas.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ic_antennas.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ic_antennas.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ic_antennas.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ic_antennas.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ic_antennas.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    ic_antennas.power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["ic_antennas.power_launched.time"]
    ic_antennas.power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ic_antennas.reference_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.reference_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    ic_antennas.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    interferometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    interferometer.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r", "interferometer.channel[:].n_e.time"]
    interferometer.channel[:].n_e.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r"]
    interferometer.channel[:].n_e.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e.positions.r"]
    interferometer.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line.time"]
    interferometer.channel[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.channel[:].n_e_line.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line.time"]
    interferometer.channel[:].n_e_line_average.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line_average.time"]
    interferometer.channel[:].n_e_line_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].n_e_line_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.channel[:].n_e_line_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].n_e_line_average.time"]
    interferometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    interferometer.channel[:].path_length_variation.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].path_length_variation.time"]
    interferometer.channel[:].path_length_variation.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].fringe_jump_correction

    Signed number of 2pi phase corrections applied to remove a fringe jump, for each time slice on which a correction has been made

    • Data Type: INT_1D
    • Coordinates: ["interferometer.channel[:].wavelength[:].fringe_jump_correction_times"]
    interferometer.channel[:].wavelength[:].fringe_jump_correction_times

    List of time slices of the pulse on which a fringe jump correction has been made

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].phase_corrected.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.channel[:].wavelength[:].phase_corrected.time"]
    interferometer.channel[:].wavelength[:].phase_corrected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.channel[:].wavelength[:].phase_to_n_e_line

    Conversion factor to be used to convert phase into line density for this wavelength

    • Units: m^-2.rad^-1
    • Data Type: FLT_0D
    interferometer.channel[:].wavelength[:].value

    Wavelength value

    • Units: m
    • Data Type: FLT_0D
    interferometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    interferometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    interferometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["interferometer.time"]
    interferometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.electrons_n.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["interferometer.electrons_n.time"]
    interferometer.electrons_n.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.electrons_n.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.electrons_n.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.electrons_n.time"]
    interferometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    interferometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    interferometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    interferometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    interferometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    interferometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    interferometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    interferometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    interferometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    interferometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    interferometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    interferometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    interferometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    interferometer.n_e_volume_average.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["interferometer.n_e_volume_average.time"]
    interferometer.n_e_volume_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    interferometer.n_e_volume_average.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    interferometer.n_e_volume_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["interferometer.n_e_volume_average.time"]
    interferometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.code.library[:].name

    Name of software

    • Data Type: STR_0D
    iron_core.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    iron_core.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["iron_core.time"]
    iron_core.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.code.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    iron_core.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    iron_core.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    iron_core.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    iron_core.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    iron_core.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    iron_core.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    iron_core.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    iron_core.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    iron_core.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    iron_core.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    iron_core.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    iron_core.segment[:].b_field

    Array of magnetic field values, for each of which the relative permeability is given

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.arcs_of_circle.r"]
    iron_core.segment[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.arcs_of_circle.r"]
    iron_core.segment[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    iron_core.segment[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].geometry.outline.r"]
    iron_core.segment[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    iron_core.segment[:].identifier

    ID of the segment

    • Data Type: STR_0D
    iron_core.segment[:].magnetisation_r.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].magnetisation_r.time"]
    iron_core.segment[:].magnetisation_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].magnetisation_z.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].magnetisation_z.time"]
    iron_core.segment[:].magnetisation_z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    iron_core.segment[:].name

    Name of the segment

    • Data Type: STR_0D
    iron_core.segment[:].permeability_relative

    Relative permeability of the iron segment

    • Data Type: FLT_1D
    • Coordinates: ["iron_core.segment[:].b_field"]
    iron_core.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.code.library[:].name

    Name of software

    • Data Type: STR_0D
    langmuir_probes.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    langmuir_probes.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.time"]
    langmuir_probes.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.code.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.embedded[:].b_field_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].b_field_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].b_field_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].distance_separatrix_midplane.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].distance_separatrix_midplane.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].fluence.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].fluence.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].fluence.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].heat_flux_parallel.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].heat_flux_parallel.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].heat_flux_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].identifier

    ID of the probe

    • Data Type: STR_0D
    langmuir_probes.embedded[:].ion_saturation_current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].ion_saturation_current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].ion_saturation_current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_parallel_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_parallel_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_kurtosis.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_skew.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].j_i_saturation_skew.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].j_i_saturation_skew.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].multi_temperature_fits[:].time"]
    langmuir_probes.embedded[:].multi_temperature_fits[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.embedded[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].n_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].n_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].name

    Name of the probe

    • Data Type: STR_0D
    langmuir_probes.embedded[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].surface_area

    Area of the probe surface exposed to the plasma (use when assuming constant effective collection area)

    • Units: m^2
    • Data Type: FLT_0D
    langmuir_probes.embedded[:].surface_area_effective.data

    Data

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].surface_area_effective.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].surface_area_effective.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.embedded[:].v_floating.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_floating.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating_sigma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_floating_sigma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_floating_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_plasma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.embedded[:].v_plasma.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.embedded[:].v_plasma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.embedded[:].time"]
    langmuir_probes.equilibrium_id.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    langmuir_probes.equilibrium_id.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.data_entry.run

    Run number

    • Data Type: INT_0D
    langmuir_probes.equilibrium_id.data_entry.user

    Username

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.name

    IDS name

    • Data Type: STR_0D
    langmuir_probes.equilibrium_id.occurrence

    IDS occurrence

    • Data Type: INT_0D
    langmuir_probes.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    langmuir_probes.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    langmuir_probes.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    langmuir_probes.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    langmuir_probes.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    langmuir_probes.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    langmuir_probes.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    langmuir_probes.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    langmuir_probes.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    langmuir_probes.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    langmuir_probes.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    langmuir_probes.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    langmuir_probes.midplane.description

    Verbose description

    • Data Type: STR_0D
    langmuir_probes.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    langmuir_probes.midplane.name

    Short string identifier

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].identifier

    ID of the probe

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].name

    Name of the probe

    • Data Type: STR_0D
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.data

    Data

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity

    Indicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity_timed

    Indicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].n_e.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].n_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.validity

    Indicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].position_average.validity_timed

    Indicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].position_average.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].time

    Time of maximum penetration of the probe during a given plunge

    • Units: s
    • Data Type: FLT_0D
    langmuir_probes.reciprocating[:].plunge[:].time_within_plunge

    Time vector for describing the dynamics within the plunge

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity

    Indicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].time_within_plunge"]
    langmuir_probes.reciprocating[:].surface_area

    Area of the surface exposed to the plasma of each collector (constant assuming negligible dependence on e.g. the magnetic field line angle)

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["langmuir_probes.reciprocating[:].plunge[:].collector"]
    langmuir_probes.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    lh_antennas.antenna[:].distance_to_antenna

    Radial distance to the antenna mouth (grid for the electron density profile). 0 at antenna mouth, increasing towards the plasma

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].efficiency.conversion

    Conversion efficiency of electric power to microwave power

    • Data Type: FLT_0D
    lh_antennas.antenna[:].efficiency.coupling

    Coupling efficiency of launched microwave power to the plasma

    • Data Type: FLT_0D
    lh_antennas.antenna[:].efficiency.transmission

    Transmission efficiency of microwave power from generator to antenna

    • Data Type: FLT_0D
    lh_antennas.antenna[:].frequency

    Frequency

    • Units: Hz
    • Data Type: FLT_0D
    lh_antennas.antenna[:].identifier

    Identifier of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    lh_antennas.antenna[:].model_name

    Name of the antenna model used for antenna spectrum computation

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].identifier

    Identifier of the module

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].name

    Name of the module

    • Data Type: STR_0D
    lh_antennas.antenna[:].module[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].phase.time"]
    lh_antennas.antenna[:].module[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_forward.time"]
    lh_antennas.antenna[:].module[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_launched.time"]
    lh_antennas.antenna[:].module[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].power_reflected.time"]
    lh_antennas.antenna[:].module[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].module[:].reflection_coefficient.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].module[:].reflection_coefficient.time"]
    lh_antennas.antenna[:].module[:].reflection_coefficient.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "lh_antennas.antenna[:].n_e.time"]
    lh_antennas.antenna[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].n_parallel_peak.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].n_parallel_peak.time"]
    lh_antennas.antenna[:].n_parallel_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].name

    Name of the antenna (unique within the set of all antennas of the experiment)

    • Data Type: STR_0D
    lh_antennas.antenna[:].phase_average.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].phase_average.time"]
    lh_antennas.antenna[:].phase_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.definition

    Definition of the reference point

    • Data Type: STR_0D
    lh_antennas.antenna[:].position.phi.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.phi.time"]
    lh_antennas.antenna[:].position.phi.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.r.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.r.time"]
    lh_antennas.antenna[:].position.r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].position.z.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].position.z.time"]
    lh_antennas.antenna[:].position.z.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_forward.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_forward.time"]
    lh_antennas.antenna[:].power_forward.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_launched.time"]
    lh_antennas.antenna[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].power_reflected.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].power_reflected.time"]
    lh_antennas.antenna[:].power_reflected.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].pressure_tank.data

    Data

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].pressure_tank.time"]
    lh_antennas.antenna[:].pressure_tank.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].reflection_coefficient.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].reflection_coefficient.time"]
    lh_antennas.antenna[:].reflection_coefficient.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].row[:].n_pol

    Refraction index in the poloidal direction. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/z

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].n_tor

    Refraction index in the toroidal direction

    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].name

    Name of the row

    • Data Type: STR_0D
    lh_antennas.antenna[:].row[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].position.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.antenna[:].row[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.antenna[:].row[:].position.time"]
    lh_antennas.antenna[:].row[:].power_density_spectrum_1d

    1D power density spectrum dP/dn_tor, as a function of time

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["lh_antennas.antenna[:].row[:].n_tor", "lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].power_density_spectrum_2d

    2D power density spectrum d2P/(dntor.dnpol), as a function of time

    • Units: W
    • Data Type: FLT_3D
    • Coordinates: ["lh_antennas.antenna[:].row[:].n_tor", "lh_antennas.antenna[:].row[:].n_pol", "lh_antennas.antenna[:].row[:].time"]
    lh_antennas.antenna[:].row[:].time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.code.library[:].name

    Name of software

    • Data Type: STR_0D
    lh_antennas.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    lh_antennas.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["lh_antennas.time"]
    lh_antennas.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.code.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    lh_antennas.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    lh_antennas.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    lh_antennas.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    lh_antennas.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    lh_antennas.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    lh_antennas.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    lh_antennas.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    lh_antennas.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    lh_antennas.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    lh_antennas.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    lh_antennas.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    lh_antennas.power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["lh_antennas.power_launched.time"]
    lh_antennas.power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    lh_antennas.reference_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    lh_antennas.reference_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    lh_antennas.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].area

    Area of each turn of the sensor; becomes effective area when multiplied by the turns

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].bandwidth_3db

    3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_pol_probe[:].field.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].field.time"]
    magnetics.b_field_pol_probe[:].field.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].field.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].field.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].field.time"]
    magnetics.b_field_pol_probe[:].identifier

    ID of the probe

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].indices_differential

    Indices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_pol_probe[:].length

    Length of the sensor along it's normal vector (n)

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].name

    Name of the probe

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear

    Array of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linear

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].non_linear_response.b_field_non_linear

    Magnetic field value taking into account the non-linear response of the probe

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear"]
    magnetics.b_field_pol_probe[:].poloidal_angle

    Angle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].toroidal_angle

    Angle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_pol_probe[:].turns

    Turns in the coil, including sign

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.b_field_pol_probe[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].voltage.time"]
    magnetics.b_field_pol_probe[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_pol_probe[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_pol_probe[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_pol_probe[:].voltage.time"]
    magnetics.b_field_tor_probe[:].area

    Area of each turn of the sensor; becomes effective area when multiplied by the turns

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].bandwidth_3db

    3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_tor_probe[:].field.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].field.time"]
    magnetics.b_field_tor_probe[:].field.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].field.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].field.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].field.time"]
    magnetics.b_field_tor_probe[:].identifier

    ID of the probe

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].indices_differential

    Indices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.b_field_tor_probe[:].length

    Length of the sensor along it's normal vector (n)

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].name

    Name of the probe

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear

    Array of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linear

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].non_linear_response.b_field_non_linear

    Magnetic field value taking into account the non-linear response of the probe

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear"]
    magnetics.b_field_tor_probe[:].poloidal_angle

    Angle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].toroidal_angle

    Angle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).

    • Units: rad
    • Data Type: FLT_0D
    magnetics.b_field_tor_probe[:].turns

    Turns in the coil, including sign

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.b_field_tor_probe[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].voltage.time"]
    magnetics.b_field_tor_probe[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.b_field_tor_probe[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.b_field_tor_probe[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.b_field_tor_probe[:].voltage.time"]
    magnetics.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.code.library[:].name

    Name of software

    • Data Type: STR_0D
    magnetics.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    magnetics.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["magnetics.time"]
    magnetics.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.code.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.diamagnetic_flux[:].data

    Data

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.diamagnetic_flux[:].time"]
    magnetics.diamagnetic_flux[:].method_name

    Name of the calculation method

    • Data Type: STR_0D
    magnetics.diamagnetic_flux[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].area

    Effective area (ratio between flux and average magnetic field over the loop)

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.flux_loop[:].flux.data

    Data

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.flux_loop[:].flux.time"]
    magnetics.flux_loop[:].flux.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].flux.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.flux_loop[:].flux.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.flux_loop[:].flux.time"]
    magnetics.flux_loop[:].gm9

    Integral of 1/R over the loop area (ratio between flux and magnetic rigidity R0.B0). Use only if ../type/index = 3 to 6, leave empty otherwise.

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].identifier

    ID of the flux loop

    • Data Type: STR_0D
    magnetics.flux_loop[:].indices_differential

    Indices (from the flux_loop array of structure) of the two flux loops used to build the flux difference flux(second index) - flux(first index). Use only if ../type/index = 6, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    magnetics.flux_loop[:].name

    Name of the flux loop

    • Data Type: STR_0D
    magnetics.flux_loop[:].position[:].phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.flux_loop[:].position[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].position[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.flux_loop[:].type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.flux_loop[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.flux_loop[:].type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.flux_loop[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.flux_loop[:].voltage.time"]
    magnetics.flux_loop[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.flux_loop[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.flux_loop[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.flux_loop[:].voltage.time"]
    magnetics.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    magnetics.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    magnetics.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    magnetics.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    magnetics.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    magnetics.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    magnetics.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    magnetics.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    magnetics.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    magnetics.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    magnetics.ip[:].data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.ip[:].time"]
    magnetics.ip[:].method_name

    Name of the calculation method

    • Data Type: STR_0D
    magnetics.ip[:].time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].area

    Effective area of the loop wrapped around the guiding centre. In case of multiple layers, sum of the areas of each layer

    • Units: m^2
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.rogowski_coil[:].current.time"]
    magnetics.rogowski_coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.rogowski_coil[:].current.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.rogowski_coil[:].current.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.rogowski_coil[:].current.time"]
    magnetics.rogowski_coil[:].identifier

    ID of the coil

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].indices_compound

    Indices (from the rogowskicoil array of structure) of the partial Rogoswkis used to build the coumpound signal (sum of the partial Rogoswki signals). Can be set to any unique integer value for each section of a compound rogowski coil. Use only if ../measurequantity/index = 5, leave empty otherwise

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    magnetics.rogowski_coil[:].measured_quantity.description

    Verbose description

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].measured_quantity.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    magnetics.rogowski_coil[:].measured_quantity.name

    Short string identifier

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].name

    Name of the coil

    • Data Type: STR_0D
    magnetics.rogowski_coil[:].position[:].phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].position[:].r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].position[:].z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.rogowski_coil[:].turns_per_metre

    Number of turns per unit length. In case of multiple layers, turns are counted for a single layer

    • Units: m^-1
    • Data Type: FLT_0D
    magnetics.shunt[:].divertor_index

    If the shunt is located on a given divertor, index of that divertor in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].identifier

    Alphanumeric identifier of the shunt

    • Data Type: STR_0D
    magnetics.shunt[:].name

    Name of the shunt

    • Data Type: STR_0D
    magnetics.shunt[:].position.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].position.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    magnetics.shunt[:].resistance

    Shunt resistance

    • Units: Ohm
    • Data Type: FLT_0D
    magnetics.shunt[:].target_index

    If the shunt is located on a divertor target, index of that target in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].tile_index

    If the shunt is located on a divertor tile, index of that tile in the divertors IDS

    • Data Type: INT_0D
    magnetics.shunt[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["magnetics.shunt[:].voltage.time"]
    magnetics.shunt[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    magnetics.shunt[:].voltage.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    magnetics.shunt[:].voltage.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["magnetics.shunt[:].voltage.time"]
    magnetics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mhd.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mhd.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mhd.time"]
    mhd.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.code.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ggd[:].a_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_r[:].values", "1...N"]
    mhd.ggd[:].a_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].a_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_tor[:].values", "1...N"]
    mhd.ggd[:].a_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].a_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].a_field_z[:].values", "1...N"]
    mhd.ggd[:].a_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].a_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].a_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_r[:].values", "1...N"]
    mhd.ggd[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_tor[:].values", "1...N"]
    mhd.ggd[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].b_field_z[:].values", "1...N"]
    mhd.ggd[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].electrons.temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].electrons.temperature[:].values", "1...N"]
    mhd.ggd[:].electrons.temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].electrons.temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].electrons.temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_r[:].values", "1...N"]
    mhd.ggd[:].j_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_tor[:].values", "1...N"]
    mhd.ggd[:].j_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_tor_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_tor_r[:].values", "1...N"]
    mhd.ggd[:].j_tor_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_tor_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_tor_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].j_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].j_z[:].values", "1...N"]
    mhd.ggd[:].j_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].j_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].j_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].mass_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].mass_density[:].values", "1...N"]
    mhd.ggd[:].mass_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].mass_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].mass_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].n_i_total[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].n_i_total[:].values", "1...N"]
    mhd.ggd[:].n_i_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].n_i_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].n_i_total[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].phi_potential[:].values", "1...N"]
    mhd.ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].psi[:].values", "1...N"]
    mhd.ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].t_i_average[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].t_i_average[:].values", "1...N"]
    mhd.ggd[:].t_i_average[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].t_i_average[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].t_i_average[:].values

    One scalar value is provided per element in the grid subset.

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd.ggd[:].velocity_parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_parallel[:].values", "1...N"]
    mhd.ggd[:].velocity_parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_parallel_over_b_field[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1.T^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_parallel_over_b_field[:].values", "1...N"]
    mhd.ggd[:].velocity_parallel_over_b_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel_over_b_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_parallel_over_b_field[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1.T^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_r[:].values", "1...N"]
    mhd.ggd[:].velocity_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_tor[:].values", "1...N"]
    mhd.ggd[:].velocity_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].velocity_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].velocity_z[:].values", "1...N"]
    mhd.ggd[:].velocity_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].velocity_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].velocity_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].vorticity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].vorticity[:].values", "1...N"]
    mhd.ggd[:].vorticity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].vorticity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].vorticity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].vorticity_over_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].vorticity_over_r[:].values", "1...N"]
    mhd.ggd[:].vorticity_over_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].vorticity_over_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].vorticity_over_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.ggd[:].zeff[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["mhd.ggd[:].zeff[:].values", "1...N"]
    mhd.ggd[:].zeff[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    mhd.ggd[:].zeff[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    mhd.ggd[:].zeff[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element"]
    mhd.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element"]
    mhd.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["mhd.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    mhd.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    mhd.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mhd.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mhd.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mhd.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mhd.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mhd.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mhd.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mhd.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mhd.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mhd.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mhd.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mhd.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mhd.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mhd_linear.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mhd_linear.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mhd_linear.time"]
    mhd_linear.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.code.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.equations.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.equations.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.equations.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.fluids_n

    Number of fluids considered in the model

    • Data Type: INT_0D
    mhd_linear.ideal_flag

    1 if ideal MHD is used to populate this IDS, 0 for non-ideal MHD

    • Data Type: INT_0D
    mhd_linear.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mhd_linear.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mhd_linear.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mhd_linear.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mhd_linear.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mhd_linear.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mhd_linear.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mhd_linear.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mhd_linear.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mhd_linear.model_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.model_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.model_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].amplitude_multiplier

    Multiplier that is needed to convert the linear mode structures to the amplitude of a non-linearly saturated mode in physical units. If empty, it means that the structures contains no information about non-linearly saturated mode

    • Units: mixed
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].energy_perturbed

    Perturbed energy associated to the mode

    • Units: J
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].growthrate

    Linear growthrate of the mode

    • Units: Hz
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].m_pol_dominant

    Dominant poloidal mode number defining the mode rational surface; for TAEs the lower of the two main m's has to be specified

    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].n_tor

    Toroidal mode number of the MHD mode

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].phase

    Additional phase offset of mode

    • Units: rad
    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].imaginary

    Imaginary part of the frequency, for a given radial position and every root found at this position

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real

    Real part of the frequency, for a given radial position and every root found at this position

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.imaginary

    Imaginary part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.real

    Real part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.imaginary

    Imaginary part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.real

    Real part

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: kg.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: kg.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.imaginary

    Imaginary part

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.real

    Real part

    • Units: kg.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.imaginary

    Imaginary part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.real

    Real part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: Pa
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: Pa
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.imaginary

    Imaginary part

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.real

    Real part

    • Units: Pa
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: V
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.imaginary

    Imaginary part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.real

    Real part

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.imaginary

    Imaginary part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.real

    Real part of the stress tensor, for various radial positions

    • Units: N.m^-2
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "1...N", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_alfven

    Alven time=R/vA=R0 sqrt(mi ni(rho))/B0

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_resistive

    Resistive time = mu0 rho*rho/1.22/etaneo

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: eV
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: eV
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.imaginary

    Imaginary part

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.real

    Real part

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: m/s
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.real

    Real part

    • Units: m/s
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].radial_mode_number

    Radial mode number

    • Data Type: FLT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T.m
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.real

    Real part

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_imaginary

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_real

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D grid

    • Units: T
    • Data Type: FLT_3D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2", "1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.imaginary

    Imaginary part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.real

    Real part

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.jacobian

    Absolute value of the jacobian of the coordinate system

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.r

    Values of the major radius on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_contravariant

    Contravariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_covariant

    Covariant metric tensor on every point of the grid described by grid_type

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2", "1...3", "1...3"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.z

    Values of the Height on the grid

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1", "mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2"]
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.description

    Verbose description

    • Data Type: STR_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    mhd_linear.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["mhd_linear.time"]
    mhd_linear.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].geometric_coefficients

    Set of 9 geometric coefficients providing the MSE polarisation angle as a function of the local electric and magnetic field components (these are related to the angle between beam and line of sight). The list is ordered as follows : coefficients of BZ, BR, Bphi, ER (numerator of the MSE angle expression); coefficients of BZ, BR, Bphi, ER, EZ (denominator)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...9"]
    mse.channel[:].active_spatial_resolution[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].active_spatial_resolution[:].width.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    mse.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].aperture[:].outline.x1"]
    mse.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    mse.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].detector.outline.x1"]
    mse.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    mse.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    mse.channel[:].polarisation_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["mse.channel[:].polarisation_angle.time"]
    mse.channel[:].polarisation_angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    mse.channel[:].polarisation_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    mse.channel[:].polarisation_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["mse.channel[:].polarisation_angle.time"]
    mse.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.code.library[:].name

    Name of software

    • Data Type: STR_0D
    mse.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    mse.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["mse.time"]
    mse.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.code.repository

    URL of software repository

    • Data Type: STR_0D
    mse.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    mse.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    mse.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    mse.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    mse.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    mse.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    mse.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    mse.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    mse.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    mse.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    mse.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    mse.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    mse.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    mse.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    mse.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    mse.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    mse.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.code.library[:].name

    Name of software

    • Data Type: STR_0D
    nbi.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    nbi.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["nbi.time"]
    nbi.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.code.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    nbi.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    nbi.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    nbi.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    nbi.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    nbi.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    nbi.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    nbi.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    nbi.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    nbi.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    nbi.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    nbi.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    nbi.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    nbi.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    nbi.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    nbi.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    nbi.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    nbi.unit[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].aperture[:].outline.x1"]
    nbi.unit[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].available_launch_power

    Available launch power

    • Units: W
    • Data Type: FLT_0D
    nbi.unit[:].beam_current_fraction.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "nbi.unit[:].beam_current_fraction.time"]
    nbi.unit[:].beam_current_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beam_power_fraction.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "nbi.unit[:].beam_power_fraction.time"]
    nbi.unit[:].beam_power_fraction.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beamlets_group[:].angle

    Angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal plane

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].beamlets.angles

    Angle of inclination between a line at the centre of a beamlet and the horizontal plane, for each beamlet

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].beamlets_group[:].beamlets.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.power_fractions

    Fraction of power of a unit injected by each beamlet

    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].beamlets.tangency_radii

    Tangency radius (major radius where the central line of a beamlet is tangent to a circle around the torus), for each beamlet

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].beamlets_group[:].beamlets.positions.r"]
    nbi.unit[:].beamlets_group[:].direction

    Direction of the beam seen from above the torus: -1 = clockwise; 1 = counter clockwise

    • Data Type: INT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].horizontal

    The horiztonal beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].particles_fraction

    Fraction of injected particles in the component

    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].divergence_component[:].vertical

    The vertical beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.focal_length_horizontal

    Horizontal focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum horizontal width

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.focal_length_vertical

    Vertical focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum vertical width

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.width_min_horizontal

    The horizontal width (Full Width at Half Maximum) of the beamlets group at the horizontal focal point

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].focus.width_min_vertical

    The vertical width (Full Width at Half Maximum) of the beamlets group at the vertical focal point

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tangency_radius

    Tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_angle

    Variation of the angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal plane

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].delta_tangency_radius

    Variation of the tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].tilting[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].width_horizontal

    Horizontal width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].beamlets_group[:].width_vertical

    Vertical width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].efficiency.conversion

    Conversion efficiency of electric power to neutral beam power

    • Data Type: FLT_0D
    nbi.unit[:].efficiency.transmission

    Transmission efficiency of neutral beam from source to port

    • Data Type: FLT_0D
    nbi.unit[:].energy.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].energy.time"]
    nbi.unit[:].energy.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].identifier

    ID of the NBI unit

    • Data Type: STR_0D
    nbi.unit[:].name

    Name of the NBI unit

    • Data Type: STR_0D
    nbi.unit[:].power_launched.data

    Data

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].power_launched.time"]
    nbi.unit[:].power_launched.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].source.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    nbi.unit[:].source.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    nbi.unit[:].source.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    nbi.unit[:].source.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["nbi.unit[:].source.outline.x1"]
    nbi.unit[:].source.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].source.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    nbi.unit[:].species.a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    nbi.unit[:].species.label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    nbi.unit[:].species.z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    neutron_diagnostic.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].name

    Name of software

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    neutron_diagnostic.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.code.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].adc.bias

    ADC signal bias

    • Units: V
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.discriminator_level_lower

    Lower level discriminator of ADC

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.discriminator_level_upper

    Upper level discriminator of ADC

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.impedance

    ADC impedance

    • Units: ohm
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.input_range

    ADC input range

    • Units: V
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].adc.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].adc.sampling_rate

    Number of samples recorded per second

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].aperture[:].outline.x1"]
    neutron_diagnostic.detector[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].b_field_sensor.amplitude.time"]
    neutron_diagnostic.detector[:].b_field_sensor.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].b_field_sensor.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].b_field_sensor.frequency.time"]
    neutron_diagnostic.detector[:].b_field_sensor.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].b_field_sensor.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].b_field_sensor.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].b_field_sensor.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].energy_band[:].energies"]
    neutron_diagnostic.detector[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.x

    Components along X axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.y

    Component along Y axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.direction_to_detector.z

    Component along Z axis for each voxel

    • Units: m
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.emission_grid.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].field_of_view.solid_angle

    Average solid angle that the detector covers within the voxel

    • Units: sr
    • Data Type: FLT_3D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi"]
    neutron_diagnostic.detector[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].geometry.outline.x1"]
    neutron_diagnostic.detector[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values

    Array of values for the event

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values

    Array of values for the event

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].green_functions.neutron_flux

    Grouped neutron flux in the detector from one neutron energy bin emitted by the current plasma voxel towards the detector

    • Units: m^-2.neutron^-1
    • Data Type: FLT_5D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi", "neutron_diagnostic.detector[:].green_functions.source_neutron_energies", "neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values"]
    neutron_diagnostic.detector[:].green_functions.neutron_flux_integrated_flags

    Array of flags telling, for each coordinate of the neutronflux, whether the neutronflux has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1

    • Data Type: INT_1D
    • Coordinates: ["1...5"]
    neutron_diagnostic.detector[:].green_functions.response_function

    Number of events occurring in the detector from one neutron energy bin emitted by the current plasma voxel towards the detector

    • Units: events.neutron^-1
    • Data Type: FLT_5D
    • Coordinates: ["neutron_diagnostic.detector[:].field_of_view.emission_grid.r", "neutron_diagnostic.detector[:].field_of_view.emission_grid.z", "neutron_diagnostic.detector[:].field_of_view.emission_grid.phi", "neutron_diagnostic.detector[:].green_functions.source_neutron_energies", "neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values"]
    neutron_diagnostic.detector[:].green_functions.response_function_integrated_flags

    Array of flags telling, for each coordinate of the responsefunction, whether the responsefunction has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1

    • Data Type: INT_1D
    • Coordinates: ["1...5"]
    neutron_diagnostic.detector[:].green_functions.source_neutron_energies

    Array of source neutron energy bins

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].material.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].material.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].count_limit_max

    Maximum count limit under which the detector response is linear

    • Units: counts.s^-1
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].mode[:].count_limit_min

    Minimum count limit above which the detector response is linear

    • Units: counts.s^-1
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].mode[:].counting.data

    Data

    • Units: counts.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].mode[:].counting.time"]
    neutron_diagnostic.detector[:].mode[:].counting.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].mode[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].mode[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].mode[:].spectrum.data

    Data

    • Units: counts.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "neutron_diagnostic.detector[:].mode[:].spectrum.time"]
    neutron_diagnostic.detector[:].mode[:].spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].name

    Name of the detector

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].nuclei_n

    Number of target nuclei in the dectector

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_high_voltage.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time"]
    neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_low_voltage.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time"]
    neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature

    Temperature of the detector

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.detector[:].temperature_sensor.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].temperature_sensor.amplitude.time"]
    neutron_diagnostic.detector[:].temperature_sensor.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature_sensor.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].temperature_sensor.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].temperature_sensor.frequency.time"]
    neutron_diagnostic.detector[:].temperature_sensor.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].temperature_sensor.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].temperature_sensor.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].temperature_sensor.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].test_generator.amplitude.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].test_generator.amplitude.time"]
    neutron_diagnostic.detector[:].test_generator.amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].test_generator.fall_time

    Peak fall time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].test_generator.frequency.data

    Data

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.detector[:].test_generator.frequency.time"]
    neutron_diagnostic.detector[:].test_generator.frequency.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.detector[:].test_generator.power_switch

    Power switch (1=on, 0=off)

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].test_generator.rise_time

    Peak rise time

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.detector[:].test_generator.shape.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.detector[:].test_generator.shape.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.detector[:].test_generator.shape.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.fusion_power

    Fusion power reconstructed from the detectors signals

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    neutron_diagnostic.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    neutron_diagnostic.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    neutron_diagnostic.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    neutron_diagnostic.neutron_flux_total

    Total Neutron Flux reconstructed from the detectors signals

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["neutron_diagnostic.time"]
    neutron_diagnostic.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.first_wall.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.first_wall.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    neutronics.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    neutronics.time_slice[:].wall_loading.flux_r

    Average radial component of the neutron flux

    • Units: W/m^2
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time_slice[:].wall_loading.flux_z

    Average vertical component of the neutron flux

    • Units: W/m^2
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    neutronics.time_slice[:].wall_loading.power

    Local neutron power (ie. integrated neutron flux)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["neutronics.first_wall.r"]
    ntms.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.code.library[:].name

    Name of software

    • Data Type: STR_0D
    ntms.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    ntms.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["ntms.time"]
    ntms.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.code.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    ntms.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    ntms.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    ntms.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    ntms.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    ntms.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    ntms.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    ntms.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    ntms.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    ntms.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    ntms.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    ntms.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    ntms.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    ntms.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    ntms.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    ntms.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ntms.time_slice[:].mode[:].calculation_method

    Description of how the mode evolution is calculated

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].delta_diff

    Extra diffusion coefficient for the transport equations of Te, ne, Ti

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    ntms.time_slice[:].mode[:].deltaw[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].deltaw[:].value

    Value of the contribution

    • Units: m^-1
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.calculation_method

    Description of how the mode evolution is calculated

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.delta_diff

    Extra diffusion coefficient for the transport equations of Te, ne, Ti

    • Units: m^2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].value

    Value of the contribution

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dfrequency_dt

    Time derivative of the frequency of the mode

    • Units: s^-2
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dphase_dt

    Time derivative of the phase of the mode

    • Units: rad/s
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.dwidth_dt

    Time derivative of the full width of the mode

    • Units: m/s
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].detailed_evolution.phase

    Phase of the mode

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.rho_tor

    Flux coordinate on which the mode is centred

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.rho_tor_norm

    Normalised flux coordinate on which the mode is centred

    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.time_detailed

    Time array used to describe the detailed evolution of the NTM

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    ntms.time_slice[:].mode[:].detailed_evolution.torque[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].detailed_evolution.torque[:].value

    Value of the contribution

    • Units: kg.m^2.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].detailed_evolution.width

    Full width of the mode

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time_slice[:].mode[:].detailed_evolution.time_detailed"]
    ntms.time_slice[:].mode[:].dfrequency_dt

    Time derivative of the frequency of the mode

    • Units: s^-2
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].dphase_dt

    Time derivative of the phase of the mode

    • Units: rad/s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].dwidth_dt

    Time derivative of the full width of the mode

    • Units: m/s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].frequency

    Frequency of the mode

    • Units: Hz
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.cause

    Cause of the mode onset

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].onset.m_pol

    Poloidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.n_tor

    Toroidal mode number

    • Data Type: INT_0D
    ntms.time_slice[:].mode[:].onset.phase

    Phase of the mode at onset

    • Units: rad
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.time_offset

    Offset time (when a mode disappears). If the mode reappears later in the simulation, use another index of the mode array of structure

    • Units: s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.time_onset

    Onset time

    • Units: s
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].onset.width

    Seed island full width at onset time

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].phase

    Phase of the mode

    • Units: rad
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].rho_tor

    Flux coordinate on which the mode is centred

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].rho_tor_norm

    Normalised flux coordinate on which the mode is centred

    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].torque[:].name

    Name of the contribution

    • Data Type: STR_0D
    ntms.time_slice[:].mode[:].torque[:].value

    Value of the contribution

    • Units: kg.m^2.s^-2
    • Data Type: FLT_0D
    ntms.time_slice[:].mode[:].width

    Full width of the mode

    • Units: m
    • Data Type: FLT_0D
    ntms.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    ntms.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["ntms.time"]
    ntms.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    operational_instrumentation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["operational_instrumentation.time"]
    operational_instrumentation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.code.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    operational_instrumentation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    operational_instrumentation.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].acceleration.data

    Data

    • Units: m.s^-2
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].acceleration.time"]
    operational_instrumentation.sensor[:].acceleration.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].attachement_points[:].x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_points[:].y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_points[:].z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].attachement_uris

    IMAS URI of the system(s) to which this sensor is attached. Two for displacement sensors, one for the other types of sensors

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].direction_second.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].gauge_length

    Length of the strain gauge

    • Units: m
    • Data Type: FLT_0D
    operational_instrumentation.sensor[:].identifier

    ID of the sensor

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].length.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].length.time"]
    operational_instrumentation.sensor[:].length.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].name

    Name of the sensor

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].strain.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].strain.time"]
    operational_instrumentation.sensor[:].strain.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].strain_rosette.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "operational_instrumentation.sensor[:].strain_rosette.time"]
    operational_instrumentation.sensor[:].strain_rosette.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].temperature.data

    Data

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["operational_instrumentation.sensor[:].temperature.time"]
    operational_instrumentation.sensor[:].temperature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    operational_instrumentation.sensor[:].type.description

    Verbose description

    • Data Type: STR_0D
    operational_instrumentation.sensor[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    operational_instrumentation.sensor[:].type.name

    Short string identifier

    • Data Type: STR_0D
    operational_instrumentation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pellets.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pellets.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pellets.time"]
    pellets.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.code.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pellets.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pellets.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pellets.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pellets.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pellets.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pellets.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pellets.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pellets.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pellets.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pellets.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pellets.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pellets.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pellets.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pellets.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    pellets.launcher[:].name

    Name of the launcher (unique within the set of all launchers of the experiment)

    • Data Type: STR_0D
    pellets.launcher[:].shape.size

    Size of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the length

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.launcher[:].shape.type.description

    Verbose description

    • Data Type: STR_0D
    pellets.launcher[:].shape.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.launcher[:].shape.type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.launcher[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.launcher[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.launcher[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].frequency

    Frequency of pellets launched

    • Units: Hz
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].density

    Material density of the species in the pellet

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].fraction

    Atomic fraction of the species in the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].sublimation_energy

    Sublimation energy per atom

    • Units: eV
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].layer[:].thickness

    Layer thickness

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_geometry.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].path_profiles.ablated_particles

    Number of ablated particles (electrons) along the pellet path

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.ablation_rate

    Ablation rate (electrons) along the pellet path

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.distance

    Distance along the pellet path, with the origin taken at pathgeometry/firstpoint. Used as the main coordinate for the path_profiles structure

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].path_profiles.n_e

    Electron density along the pellet path

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.position.r"]
    pellets.time_slice[:].pellet[:].path_profiles.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].path_profiles.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.position.r"]
    pellets.time_slice[:].pellet[:].path_profiles.psi

    Poloidal flux along the pellet path

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm

    Normalised toroidal coordinate along the pellet path

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm_drift

    Difference to due ExB drifts between the ablation and the final deposition locations, in terms of the normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.t_e

    Electron temperature along the pellet path

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].path_profiles.velocity

    Pellet velocity along the pellet path

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["pellets.time_slice[:].pellet[:].path_profiles.distance"]
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].propellant_gas.label

    String identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].propellant_gas.molecules_n

    Number of molecules of the propellant gas injected in the vacuum vessel when launching the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].shape.size

    Size of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the length

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pellets.time_slice[:].pellet[:].shape.type.description

    Verbose description

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].shape.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pellets.time_slice[:].pellet[:].shape.type.name

    Short string identifier

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].density

    Material density of the species in the pellet

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].fraction

    Atomic fraction of the species in the pellet

    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    pellets.time_slice[:].pellet[:].species[:].sublimation_energy

    Sublimation energy per atom

    • Units: eV
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pellets.time_slice[:].pellet[:].velocity_initial

    Initial velocity of the pellet as it enters the vaccum chamber

    • Units: m.s^-1
    • Data Type: FLT_0D
    pellets.time_slice[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    pf_active.circuit[:].connections

    Description of the supplies and coils connections (nodes) across the circuit. Nodes of the circuit are listed as the first dimension of the matrix. Supplies (listed first) and coils (listed second) SIDES are listed as the second dimension. Thus the second dimension has a size equal to 2*(Nsupplies+Ncoils). Nsupplies (resp. Ncoils) is the total number of supplies (resp. coils) listed in the supply (resp.coil) array of structure, i.e. including also supplies/coils that are not part of the actual circuit. The (i,j) matrix elements are 1 if the j-th supply or coil side is connected to the i-th node, or 0 otherwise. For coils, sides are listed so that a current flowing from side 1 to side 2 (inside the coil) is positive (i.e. counter-clockwise when seen from above).

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    pf_active.circuit[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.circuit[:].current.time"]
    pf_active.circuit[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.circuit[:].identifier

    ID of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].name

    Name of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].type

    Type of the circuit

    • Data Type: STR_0D
    pf_active.circuit[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.circuit[:].voltage.time"]
    pf_active.circuit[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_active.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_active.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_active.time"]
    pf_active.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.coil[:].b_field_max

    List of values of the maximum magnetic field on the conductor surface (coordinate for currentlimitmax)

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].b_field_max_timed.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].b_field_max_timed.time"]
    pf_active.coil[:].b_field_max_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].current.time"]
    pf_active.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].current_limit_max

    Maximum tolerable current in the conductor

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["pf_active.coil[:].b_field_max", "pf_active.coil[:].temperature"]
    pf_active.coil[:].element[:].area

    Cross-sectional areas of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.arcs_of_circle.r"]
    pf_active.coil[:].element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.arcs_of_circle.r"]
    pf_active.coil[:].element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_active.coil[:].element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].element[:].geometry.outline.r"]
    pf_active.coil[:].element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_active.coil[:].element[:].identifier

    Identifier of this element

    • Data Type: STR_0D
    pf_active.coil[:].element[:].name

    Name of this element

    • Data Type: STR_0D
    pf_active.coil[:].element[:].turns_with_sign

    Number of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)

    • Data Type: FLT_0D
    pf_active.coil[:].energy_limit_max

    Maximum Energy to be dissipated in the coil

    • Units: J
    • Data Type: FLT_0D
    pf_active.coil[:].force_radial.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_radial.time"]
    pf_active.coil[:].force_radial.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_radial_crushing.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_radial_crushing.time"]
    pf_active.coil[:].force_radial_crushing.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_vertical.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_vertical.time"]
    pf_active.coil[:].force_vertical.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].force_vertical_crushing.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].force_vertical_crushing.time"]
    pf_active.coil[:].force_vertical_crushing.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].function[:].description

    Verbose description

    • Data Type: STR_0D
    pf_active.coil[:].function[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_active.coil[:].function[:].name

    Short string identifier

    • Data Type: STR_0D
    pf_active.coil[:].identifier

    Alphanumeric identifier of coils used for convenience

    • Data Type: STR_0D
    pf_active.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    pf_active.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_active.coil[:].resistance_additional.data

    Data

    • Units: Ohm
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].resistance_additional.time"]
    pf_active.coil[:].resistance_additional.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].temperature

    List of values of the conductor temperature (coordinate for currentlimitmax)

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.coil[:].voltage.time"]
    pf_active.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.combination_matrix

    Force limits are expressed as a linear combination of the forces on each individual coil. The weights of the linear combination are given by this matrix, while the limits are given by the sibling nodes limitmin and limitmax. Each row of this matrix corresponds to a force limit. The columns represent, for each coil, the 4 types of forces on the coil namely [coil1radial, coil1vertical, coil1radialcrush, coil1verticalcrush, coil2radial, coil2vertical, coil2radialcrush, coil2verticalcrush, ...]. There are therefore 4*coils_n columns.

    • Data Type: FLT_2D
    • Coordinates: ["pf_active.force_limits.limit_max", "1...N"]
    pf_active.force_limits.force.data

    Data

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.force_limits.force.time"]
    pf_active.force_limits.force.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.limit_max

    Maximum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unbounded

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.force_limits.limit_min

    Minimum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unbounded

    • Units: N
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.force_limits.limit_max"]
    pf_active.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_active.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_active.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_active.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_active.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_active.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_active.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_active.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_active.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_active.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_active.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_active.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_active.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    pf_active.supply[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.supply[:].current.time"]
    pf_active.supply[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].current_limit_max

    Maximum current in the supply

    • Units: A
    • Data Type: FLT_0D
    pf_active.supply[:].current_limit_min

    Minimum current in the supply

    • Units: A
    • Data Type: FLT_0D
    pf_active.supply[:].current_limiter_gain

    Gain to prevent overcurrent in a linear model of the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.supply[:].delay

    Pure delay in the supply

    • Units: s
    • Data Type: FLT_0D
    pf_active.supply[:].energy_limit_max

    Maximum energy to be dissipated in the supply during a pulse

    • Units: J
    • Data Type: FLT_0D
    pf_active.supply[:].filter_denominator

    Coefficients of the denominator, in increasing order : b0 + b1s + ... + bms^m; used for a linear supply description

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].filter_numerator

    Coefficients of the numerator, in increasing order : a0 + a1s + ... + ans^n; used for a linear supply description

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].identifier

    Identifier of the supply

    • Data Type: STR_0D
    pf_active.supply[:].name

    Name of the PF supply

    • Data Type: STR_0D
    pf_active.supply[:].nonlinear_model

    Description of the nonlinear transfer function of the supply

    • Data Type: STR_0D
    pf_active.supply[:].resistance

    Power supply internal resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_active.supply[:].type

    Type of the supply; TBD add free description of non-linear power supplies

    • Data Type: INT_0D
    pf_active.supply[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["pf_active.supply[:].voltage.time"]
    pf_active.supply[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_active.supply[:].voltage_limit_max

    Maximum voltage from the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.supply[:].voltage_limit_min

    Minimum voltage from the supply

    • Units: V
    • Data Type: FLT_0D
    pf_active.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_passive.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_passive.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_passive.time"]
    pf_passive.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_passive.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_passive.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_passive.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_passive.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_passive.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_passive.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_passive.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_passive.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_passive.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_passive.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_passive.loop[:].current

    Passive loop current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].time"]
    pf_passive.loop[:].element[:].area

    Cross-sectional areas of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.arcs_of_circle.r"]
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.loop[:].element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.arcs_of_circle.r"]
    pf_passive.loop[:].element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_passive.loop[:].element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.loop[:].element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_passive.loop[:].element[:].geometry.outline.r"]
    pf_passive.loop[:].element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_passive.loop[:].element[:].identifier

    Identifier of this element

    • Data Type: STR_0D
    pf_passive.loop[:].element[:].name

    Name of this element

    • Data Type: STR_0D
    pf_passive.loop[:].element[:].turns_with_sign

    Number of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)

    • Data Type: FLT_0D
    pf_passive.loop[:].name

    Name of the loop

    • Data Type: STR_0D
    pf_passive.loop[:].resistance

    Passive loop resistance

    • Units: Ohm
    • Data Type: FLT_0D
    pf_passive.loop[:].resistivity

    Passive loop resistivity

    • Units: Ohm.m
    • Data Type: FLT_0D
    pf_passive.loop[:].time

    Timebase for the dynamic nodes of this loop located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_passive.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pf_plasma.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pf_plasma.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pf_plasma.time"]
    pf_plasma.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.code.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.element[:].area

    Cross-sectional area of the element

    • Units: m^2
    • Data Type: FLT_0D
    pf_plasma.element[:].current

    Current in the plasma element

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].time"]
    pf_plasma.element[:].geometry.annulus.r

    Centre major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.radius_inner

    Inner radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.radius_outer

    Outer radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.annulus.z

    Centre height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.arcs_of_circle.curvature_radii

    Curvature radius of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.arcs_of_circle.r"]
    pf_plasma.element[:].geometry.arcs_of_circle.r

    Major radii of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.element[:].geometry.arcs_of_circle.z

    Height of the start point of each arc of circle

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.arcs_of_circle.r"]
    pf_plasma.element[:].geometry.geometry_type

    Type used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line')

    • Data Type: INT_0D
    pf_plasma.element[:].geometry.oblique.alpha

    Inclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).

    • Units: rad
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.beta

    Inclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.

    • Units: rad
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.length_alpha

    Length of the parallelogram side inclined with angle alpha with respect to the major radius axis

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.length_beta

    Length of the parallelogram side inclined with angle beta with respect to the height axis

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.r

    Major radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.oblique.z

    Height of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.element[:].geometry.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["pf_plasma.element[:].geometry.outline.r"]
    pf_plasma.element[:].geometry.rectangle.height

    Vertical full height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.r

    Geometric centre R

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.width

    Horizontal full width

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.rectangle.z

    Geometric centre Z

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].geometry.thick_line.thickness

    Thickness

    • Units: m
    • Data Type: FLT_0D
    pf_plasma.element[:].time

    Timebase for the dynamic nodes located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pf_plasma.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pf_plasma.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pf_plasma.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pf_plasma.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pf_plasma.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pf_plasma.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pf_plasma.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pf_plasma.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pf_plasma.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pf_plasma.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pf_plasma.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pf_plasma.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].e_field_parallel

    Parallel electric field along each field line

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].e_field_townsend

    Townsend electric field along each field line

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.b_field_lines[:].grid.dim1", "plasma_initiation.b_field_lines[:].grid.dim2"]
    plasma_initiation.b_field_lines[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.b_field_lines[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.b_field_lines[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.b_field_lines[:].lengths

    Length of each field line

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].open_fraction

    Fraction of open field lines : ratio open fields lines / (open+closed field lines)

    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].pressure

    Prefill gas pressure used in Townsend E field calculation

    • Units: Pa
    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].starting_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].starting_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].starting_positions.r"]
    plasma_initiation.b_field_lines[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.b_field_lines[:].townsend_or_closed_positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r"]
    plasma_initiation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    plasma_initiation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    plasma_initiation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["plasma_initiation.time"]
    plasma_initiation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.code.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.global_quantities.b_field_perpendicular.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.b_field_perpendicular.time"]
    plasma_initiation.global_quantities.b_field_perpendicular.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.b_field_stray.data

    Data

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.b_field_stray.time"]
    plasma_initiation.global_quantities.b_field_stray.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.connection_length.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.connection_length.time"]
    plasma_initiation.global_quantities.connection_length.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.global_quantities.coulomb_logarithm.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["plasma_initiation.global_quantities.coulomb_logarithm.time"]
    plasma_initiation.global_quantities.coulomb_logarithm.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    plasma_initiation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    plasma_initiation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    plasma_initiation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    plasma_initiation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    plasma_initiation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    plasma_initiation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    plasma_initiation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    plasma_initiation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].e_field_tor

    Toroidal component of the electric field

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.profiles_2d[:].grid.dim1", "plasma_initiation.profiles_2d[:].grid.dim2"]
    plasma_initiation.profiles_2d[:].grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.profiles_2d[:].grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    plasma_initiation.profiles_2d[:].grid.volume_element

    Elementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["plasma_initiation.profiles_2d[:].grid.dim1", "plasma_initiation.profiles_2d[:].grid.dim2"]
    plasma_initiation.profiles_2d[:].grid_type.description

    Verbose description

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    plasma_initiation.profiles_2d[:].grid_type.name

    Short string identifier

    • Data Type: STR_0D
    plasma_initiation.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    plasma_initiation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].ellipticity.data

    Data

    • Data Type: FLT_1D
    • Coordinates: ["polarimeter.channel[:].ellipticity.time"]
    polarimeter.channel[:].ellipticity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].ellipticity.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    polarimeter.channel[:].ellipticity.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.channel[:].ellipticity.time"]
    polarimeter.channel[:].ellipticity_initial

    Initial ellipticity before entering the plasma

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].faraday_angle.data

    Data

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["polarimeter.channel[:].faraday_angle.time"]
    polarimeter.channel[:].faraday_angle.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    polarimeter.channel[:].faraday_angle.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    polarimeter.channel[:].faraday_angle.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.channel[:].faraday_angle.time"]
    polarimeter.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    polarimeter.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    polarimeter.channel[:].polarisation_initial

    Initial polarisation vector before entering the plasma

    • Units: m
    • Data Type: FLT_0D
    polarimeter.channel[:].wavelength

    Wavelength used for polarimetry

    • Units: m
    • Data Type: FLT_0D
    polarimeter.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.code.library[:].name

    Name of software

    • Data Type: STR_0D
    polarimeter.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    polarimeter.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["polarimeter.time"]
    polarimeter.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.code.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    polarimeter.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    polarimeter.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    polarimeter.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    polarimeter.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    polarimeter.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    polarimeter.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    polarimeter.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    polarimeter.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    polarimeter.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    polarimeter.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    polarimeter.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    polarimeter.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.code.library[:].name

    Name of software

    • Data Type: STR_0D
    pulse_schedule.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    pulse_schedule.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.time"]
    pulse_schedule.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.code.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.ion[:].n_i_volume_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.ion[:].z_ion

    Ion charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_greenwald_fraction.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_line.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_lcfs.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_lcfs.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_line_lcfs.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_line_lcfs.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.n_e_pedestal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_pedestal_greenwald_fraction.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_profile_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_profile_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_profile_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_profile_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_volume_average.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_e_volume_average.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_e_volume_average.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_e_volume_average.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_h_over_n_d.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_h_over_n_d.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_h_over_n_d.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_h_over_n_d.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.n_t_over_n_d.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.n_t_over_n_d.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.n_t_over_n_d.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.n_t_over_n_d.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.density_control.valve[:].flow_rate.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].flow_rate.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.valve[:].flow_rate.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].flow_rate.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].identifier

    Identifier of the valve

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].name

    Name of the valve

    • Data Type: STR_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.density_control.valve[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    pulse_schedule.density_control.valve[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.density_control.zeff.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_line_of_sight.third_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.density_control.zeff_method.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.density_control.zeff_method.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.density_control.zeff_pedestal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.density_control.time"]
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].identifier

    Identifier of the beam

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].name

    Name of the beam

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].power_launched.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].power_launched.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].power_launched.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].power_launched.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].steering_angle_pol.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].steering_angle_pol.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.beam[:].steering_angle_tor.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.beam[:].steering_angle_tor.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.power_launched.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ec.power_launched.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ec.time"]
    pulse_schedule.ec.power_launched.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ec.power_launched.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ec.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.event[:].acquisition_state.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_state.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].acquisition_state.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_strategy.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].acquisition_strategy.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].acquisition_strategy.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.event[:].duration

    Duration of this event

    • Units: s
    • Data Type: FLT_0D
    pulse_schedule.event[:].identifier

    Unique identifier of this event provided by the scheduling / event handler

    • Data Type: STR_0D
    pulse_schedule.event[:].listeners

    Systems listening to this event

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pulse_schedule.event[:].provider

    System having generated this event

    • Data Type: STR_0D
    pulse_schedule.event[:].time_stamp

    Time stamp of this event

    • Units: s
    • Data Type: FLT_0D
    pulse_schedule.event[:].type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.event[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.event[:].type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.flux_control.beta_normal.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.beta_normal.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.beta_normal.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.beta_normal.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.i_plasma.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.i_plasma.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.i_plasma.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.i_plasma.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.li_3.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.li_3.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.li_3.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.li_3.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.loop_voltage.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.flux_control.loop_voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.loop_voltage.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.flux_control.loop_voltage.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.flux_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.flux_control.time"]
    pulse_schedule.flux_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ic.antenna[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].identifier

    Identifier of the antenna

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].name

    Name of the antenna

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].phase.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].phase.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].phase.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].phase.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.antenna[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.ic.antenna[:].power_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.ic.antenna[:].power_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.ic.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.ic.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.ic.time"]
    pulse_schedule.ic.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.ic.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.ic.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    pulse_schedule.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    pulse_schedule.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    pulse_schedule.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    pulse_schedule.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    pulse_schedule.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    pulse_schedule.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    pulse_schedule.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    pulse_schedule.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].frequency.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].frequency.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].frequency.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].identifier

    Identifier of the antenna

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].n_parallel.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].n_parallel.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].n_parallel.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].n_parallel.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].name

    Name of the antenna

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].phase.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].phase.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].phase.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].phase.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.antenna[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power_type.description

    Verbose description

    • Data Type: STR_0D
    pulse_schedule.lh.antenna[:].power_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    pulse_schedule.lh.antenna[:].power_type.name

    Short string identifier

    • Data Type: STR_0D
    pulse_schedule.lh.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.lh.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.lh.time"]
    pulse_schedule.lh.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.lh.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.lh.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.nbi.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.nbi.unit[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].energy.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].energy.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].energy.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].energy.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].identifier

    Identifier of the NBI unit

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].name

    Name of the NBI unit

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].power.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].power.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.nbi.time"]
    pulse_schedule.nbi.unit[:].power.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.nbi.unit[:].power.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    pulse_schedule.nbi.unit[:].species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].fraction

    Relative fraction of this species (in molecules) in the gas mixture

    • Data Type: FLT_0D
    pulse_schedule.nbi.unit[:].species[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm_width.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.launcher[:].frequency.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pellet.time"]
    pulse_schedule.pellet.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.pf_active.coil[:].current.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].current.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.coil[:].current.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].current.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].identifier

    Identifier of the coil

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.coil[:].resistance_additional.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.coil[:].resistance_additional.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.coil[:].voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].current.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].current.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].current.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].current.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].identifier

    Identifier of the supply

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].name

    Name of the supply

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].voltage.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.pf_active.supply[:].voltage.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.pf_active.time"]
    pulse_schedule.pf_active.supply[:].voltage.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.pf_active.supply[:].voltage.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.pf_active.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.position_control.active_limiter_point.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.active_limiter_point.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.active_limiter_point.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.active_limiter_point.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.active_limiter_point.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.active_limiter_point.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.boundary_outline[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.boundary_outline[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.boundary_outline[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.boundary_outline[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.boundary_outline[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.current_centroid.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.current_centroid.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.current_centroid.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.current_centroid.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.current_centroid.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_lower.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_lower.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation_lower.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation_lower.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_upper.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.elongation_upper.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.elongation_upper.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.elongation_upper.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].angle

    Angle between the direction in which the gap is measured (in the poloidal cross-section) and the horizontal axis.

    • Units: rad
    • Data Type: FLT_0D
    pulse_schedule.position_control.gap[:].identifier

    Identifier of the gap

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].name

    Name of the gap

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].r

    Major radius of the reference point

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.position_control.gap[:].value.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].value.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.gap[:].value.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.gap[:].value.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.gap[:].z

    Height of the reference point

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.position_control.geometric_axis.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.geometric_axis.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.geometric_axis.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.geometric_axis.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.geometric_axis.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.geometric_axis.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.magnetic_axis.r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.magnetic_axis.r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.magnetic_axis.z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.magnetic_axis.z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.magnetic_axis.z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.minor_radius.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.minor_radius.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.minor_radius.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.minor_radius.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.ovality.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_lower_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_lower_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_lower_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_lower_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_upper_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_upper_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.squareness_upper_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.squareness_upper_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.squareness_upper_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.strike_point[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.strike_point[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.strike_point[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.strike_point[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.strike_point[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.tilt.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.position_control.triangularity.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_inner.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_inner.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_inner.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_inner.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_lower.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_lower.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_lower.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_lower.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_minor.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_minor.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_minor.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_minor.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_outer.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_outer.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_outer.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_outer.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_upper.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.triangularity_upper.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.triangularity_upper.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.triangularity_upper.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.twist.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.x_point[:].r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].z.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.x_point[:].z.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.x_point[:].z.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.x_point[:].z.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_max.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_max.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.z_r_max.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.z_r_max.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_min.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.position_control.z_r_min.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.position_control.time"]
    pulse_schedule.position_control.z_r_min.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.position_control.z_r_min.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.profiles_control.dpressure_dpsi.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: Pa.Wb^-1
    • Data Type: FLT_2D
    • Coordinates: ["pulse_schedule.profiles_control.psi_norm", "pulse_schedule.profiles_control.time"]
    pulse_schedule.profiles_control.f_df_dpsi.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["pulse_schedule.profiles_control.psi_norm", "pulse_schedule.profiles_control.time"]
    pulse_schedule.profiles_control.psi_norm

    Radial dimension

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.profiles_control.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.tf.b_field_tor_vacuum.reference

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.b_field_tor_vacuum_r.envelope_type

    Envelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the data

    • Data Type: INT_0D
    pulse_schedule.tf.b_field_tor_vacuum_r.reference

    Reference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.b_field_tor_vacuum_r.reference_name

    Reference name (e.g. in the native pulse schedule system of the device)

    • Data Type: STR_0D
    pulse_schedule.tf.b_field_tor_vacuum_r.reference_type

    Reference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data node

    • Data Type: INT_0D
    pulse_schedule.tf.mode

    Control mode (operation mode and/or settings used by the controller)

    • Data Type: INT_1D
    • Coordinates: ["pulse_schedule.tf.time"]
    pulse_schedule.tf.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    pulse_schedule.tf.time

    Timebase for the dynamic nodes located at this level of the IDS structure and below

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    pulse_schedule.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    radiation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    radiation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["radiation.time"]
    radiation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.code.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element"]
    radiation.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element"]
    radiation.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["radiation.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    radiation.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    radiation.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    radiation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    radiation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    radiation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    radiation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    radiation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    radiation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    radiation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    radiation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    radiation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    radiation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    radiation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    radiation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].electrons.emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].electrons.emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].electrons.emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].ion[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].ion[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].ggd[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].neutral[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values", "1...N"]
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].ggd[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].ggd[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].ggd[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power

    Total power emitted by all species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_electrons

    Power emitted by electrons

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_ion_total

    Total power emitted by all ion species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_lcfs.power_neutral_total

    Total power emitted by all neutral species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power

    Total power emitted by all species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_electrons

    Power emitted by electrons

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_ion_total

    Total power emitted by all ion species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].inside_vessel.power_neutral_total

    Total power emitted by all neutral species

    • Units: W
    • Data Type: FLT_0D
    radiation.process[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.process[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].electrons.emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].electrons.power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].emissivity_ion_total

    Emissivity (summed over ion species)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].emissivity_neutral_total

    Emissivity (summed over neutral species)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.process[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].ion[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].label

    String identifying the neutral species (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].emissivity

    Emissivity from this species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].power_inside

    Radiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    radiation.process[:].profiles_1d[:].power_inside_ion_total

    Total power from ion species (summed over ion species) inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].power_inside_neutral_total

    Total power from ion species (summed over neutral species) inside the flux surface (volume integral of the emissivity inside the flux surface)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["radiation.process[:].profiles_1d[:].grid.rho_tor_norm"]
    radiation.process[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    radiation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    radiation.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["radiation.time"]
    radiation.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    real_time_data.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.code.library[:].name

    Name of software

    • Data Type: STR_0D
    real_time_data.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    real_time_data.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.time"]
    real_time_data.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.code.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    real_time_data.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    real_time_data.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    real_time_data.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    real_time_data.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    real_time_data.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    real_time_data.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    real_time_data.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    real_time_data.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    real_time_data.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    real_time_data.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    real_time_data.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    real_time_data.topic[:].name

    Topic name

    • Data Type: STR_0D
    real_time_data.topic[:].sample

    Index of sample (time stamp counter)

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].signal[:].allocated_position

    Allocation of signal to a position in the SDN (1..N), or several positions in case of signal reshaping; this will be implementation specific

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    real_time_data.topic[:].signal[:].data_str

    Signal data (e.g. diagnostic signal or PCS command), serialized as a string

    • Data Type: STR_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].signal[:].data_type

    Signal data type

    • Data Type: STR_0D
    real_time_data.topic[:].signal[:].name

    Signal name

    • Data Type: STR_0D
    real_time_data.topic[:].signal[:].quality

    Indicator of the quality of the signal. Following ITER PCS documentation (https://user.iter.org/?uid=354SJ3&action=get_document), possible values are: 1 - GOOD (the nominal state); 2 - INVALID (data no usable); 3 - DATA INTEGRITY ERROR (e.g. out of bounds with respect to expectations, calibration error,...)

    • Data Type: INT_1D
    • Coordinates: ["real_time_data.topic[:].time_stamp"]
    real_time_data.topic[:].time_stamp

    Time of creation for all signals belonging to this topic. A set of time stamps can be recorded if needed

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].amplitude.time"]
    reflectometer_fluctuation.channel[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1"]
    reflectometer_fluctuation.channel[:].antenna_detection_static.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_detection_static.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1"]
    reflectometer_fluctuation.channel[:].antenna_emission_static.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antenna_emission_static.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].antennas_orientation[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.e_field_radial

    Radial electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.radial_width

    Width in the radial direction over which fluctuating profiles are processed

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.shift

    Doppler frequency shift (for the main peak of the power spectrum)

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].doppler.time_width

    Width of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].doppler.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].doppler.wavenumber

    Wavenumber probed by the diagnostic

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.channel[:].doppler.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.dn_e_over_n_e

    Relative amplitude of the density fluctuations post-processed for swept and fixed frequency (profile/one point)

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_level.time"]
    reflectometer_fluctuation.channel[:].fluctuations_level.radial_width

    Width in the radial direction over which fluctuating profiles are processed

    • Units: m
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].fluctuations_level.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_level.time_width

    Width of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier

    Array of frequencies used for the Fourier transform

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.power_log

    Power spectrum in log scale

    • Units: dB
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier", "reflectometer_fluctuation.channel[:].fluctuations_spectrum.time"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].fluctuations_spectrum.time_width

    Width of the time interval over which the spectrum is processed. By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.channel[:].frequencies.data

    Data

    • Units: Hz
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].frequencies.time"]
    reflectometer_fluctuation.channel[:].frequencies.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    reflectometer_fluctuation.channel[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].phase.time"]
    reflectometer_fluctuation.channel[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].raw_signal.i_component

    I component of the IQ detector used to retrieve the phase of signal's envelope

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].raw_signal.time"]
    reflectometer_fluctuation.channel[:].raw_signal.q_component

    Q component of the IQ detector used to retrieve the phase of signal's envelope

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_fluctuation.channel[:].raw_signal.time"]
    reflectometer_fluctuation.channel[:].raw_signal.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.channel[:].sweep_time

    Duration of a sweep

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].name

    Name of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["reflectometer_fluctuation.time"]
    reflectometer_fluctuation.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.code.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    reflectometer_fluctuation.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_fluctuation.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_fluctuation.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.psi_normalization.time"]
    reflectometer_fluctuation.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_fluctuation.psi_normalization.time"]
    reflectometer_fluctuation.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_fluctuation.type

    Type of reflectometer (frequency_swept, radar, ...)

    • Data Type: STR_0D
    reflectometer_profile.channel[:].amplitude.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].amplitude.time"]
    reflectometer_profile.channel[:].amplitude.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_detection.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_profile.channel[:].antenna_detection.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_detection.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.channel[:].antenna_detection.outline.x1"]
    reflectometer_profile.channel[:].antenna_detection.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    reflectometer_profile.channel[:].antenna_emission.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].antenna_emission.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.channel[:].antenna_emission.outline.x1"]
    reflectometer_profile.channel[:].antenna_emission.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].cut_off_frequency

    Cut-off frequency as a function of measurement position and time

    • Units: Hz
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].frequencies

    Array of frequencies scanned during a sweep

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_detection.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].line_of_sight_emission.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    reflectometer_profile.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    reflectometer_profile.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    reflectometer_profile.channel[:].phase.data

    Data

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].phase.time"]
    reflectometer_profile.channel[:].phase.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.channel[:].n_e.time"]
    reflectometer_profile.channel[:].sweep_time

    Duration of a sweep

    • Units: s
    • Data Type: FLT_0D
    reflectometer_profile.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].name

    Name of software

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    reflectometer_profile.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["reflectometer_profile.time"]
    reflectometer_profile.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.code.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    reflectometer_profile.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    reflectometer_profile.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    reflectometer_profile.n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.psi

    Poloidal flux

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.rho_tor_norm

    Normalised toroidal flux coordinate

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.theta

    Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "reflectometer_profile.n_e.time"]
    reflectometer_profile.psi_normalization.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.psi_normalization.time"]
    reflectometer_profile.psi_normalization.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["reflectometer_profile.psi_normalization.time"]
    reflectometer_profile.psi_normalization.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    reflectometer_profile.type

    Type of reflectometer (frequency_swept, radar, ...)

    • Data Type: STR_0D
    refractometer.channel[:].bandwidth[:].frequency_main

    Main frequency used to probe the plasma (before upshifting and modulating)

    • Units: Hz
    • Data Type: FLT_0D
    refractometer.channel[:].bandwidth[:].i_component

    I component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vector

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].bandwidth[:].n_e_line.time"]
    refractometer.channel[:].bandwidth[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].phase

    Phase of the envelope of the probing signal, relative to the phase at launch

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].phase_quadrature.data

    Data

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].phase_quadrature.time"]
    refractometer.channel[:].bandwidth[:].phase_quadrature.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].q_component

    Q component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vector

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].bandwidth[:].time

    Timebase for this bandwidth

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].bandwidth[:].time_detector

    High sampling timebase of the IQ-detector signal measurements

    • Units: s
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].bandwidth[:].time"]
    refractometer.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    refractometer.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    refractometer.channel[:].mode

    Detection mode "X" or "O"

    • Data Type: STR_0D
    refractometer.channel[:].n_e_line.data

    Data

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["refractometer.channel[:].n_e_line.time"]
    refractometer.channel[:].n_e_line.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.channel[:].n_e_profile_approximation.formula.description

    Verbose description

    • Data Type: STR_0D
    refractometer.channel[:].n_e_profile_approximation.formula.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    refractometer.channel[:].n_e_profile_approximation.formula.name

    Short string identifier

    • Data Type: STR_0D
    refractometer.channel[:].n_e_profile_approximation.parameters

    Values of the formula's parameters alpha1, ..., alphaN

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "refractometer.channel[:].n_e_line.time"]
    refractometer.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    refractometer.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.code.library[:].name

    Name of software

    • Data Type: STR_0D
    refractometer.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    refractometer.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["refractometer.time"]
    refractometer.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.code.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    refractometer.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    refractometer.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    refractometer.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    refractometer.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    refractometer.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    refractometer.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    refractometer.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    refractometer.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    refractometer.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    refractometer.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    refractometer.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    refractometer.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    refractometer.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    refractometer.type

    Type of refractometer (differential, impulse, ...)

    • Data Type: STR_0D
    requirements.Psol_R

    Psol / R

    • Units: W/m
    • Data Type: FLT_0D
    requirements.beta_normal

    Normalized total plasma beta (MHD)

    • Data Type: FLT_0D
    requirements.coil_j_margin

    Magnet coil Jcrit / Jmax

    • Data Type: FLT_0D
    requirements.coil_stress_margin

    Magnet coil yieldstress / maxstress

    • Data Type: FLT_0D
    requirements.cost

    Total FPP cost

    • Units: $M
    • Data Type: FLT_0D
    requirements.flattop_duration

    Duration of the flattop (use Inf for steady-state)

    • Units: s
    • Data Type: FLT_0D
    requirements.h98y2

    H98y2 ITER elmy H-mode confinement scaling factor

    • Data Type: FLT_0D
    requirements.hds03

    Petty 2003 H-mode thermal energy confinement scaling factor

    • Data Type: FLT_0D
    requirements.lh_power_threshold_fraction

    Fraction of the LH power threshold

    • Data Type: FLT_0D
    requirements.ne_peaking

    On-axis electron density / volume-averaged electron denstiy

    • Data Type: FLT_0D
    requirements.power_electric_net

    Net electric power generated by the fusion power plant

    • Units: W
    • Data Type: FLT_0D
    requirements.q95

    Edge safety factor

    • Data Type: FLT_0D
    requirements.q_pol_omp

    Poloidal heat flux at the outer midplane

    • Units: W/m^2
    • Data Type: FLT_0D
    requirements.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    requirements.tritium_breeding_ratio

    Tritium breeding ratio of the whole plant

    • Data Type: FLT_0D
    runaway_electrons.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.code.library[:].name

    Name of software

    • Data Type: STR_0D
    runaway_electrons.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    runaway_electrons.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.code.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values", "1...N"]
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values", "1...N"]
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.ggd[:].temperature

    Reference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.distribution.ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.distribution.gyro_type

    Defines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth point

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].coordinate_identifier[:].name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics

    Array of bounce harmonics k

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.expressions

    List of the expressions f(ntor,mpol,k,q,...) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.m_pol

    Array of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDS

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.n_tor

    Array of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from above

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals.values

    Values of the orbit integrals

    • Data Type: CPX_5D
    • Coordinates: ["runaway_electrons.distribution.markers[:].orbit_integrals.expressions", "runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].orbit_integrals.n_tor", "runaway_electrons.distribution.markers[:].orbit_integrals.m_pol", "runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions

    List of the expressions f(eq) used in the orbit integrals

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit

    Time array along the markers last orbit

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.distribution.markers[:].orbit_integrals_instant.values

    Values of the orbit integrals

    • Data Type: CPX_3D
    • Coordinates: ["runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions", "runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit"]
    runaway_electrons.distribution.markers[:].positions

    Position of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinates

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.distribution.markers[:].weights", "runaway_electrons.distribution.markers[:].coordinate_identifier"]
    runaway_electrons.distribution.markers[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.distribution.markers[:].toroidal_mode

    In case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is described

    • Data Type: INT_0D
    runaway_electrons.distribution.markers[:].weights

    Weight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markers

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.e_field_critical_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.e_field_critical_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.e_field_critical_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.ggd_fluid[:].current_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].current_density[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].current_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].current_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].current_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].density[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].e_field_critical[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].e_field_critical[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_critical[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: J.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values

    One scalar value is provided per element in the grid subset.

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values

    One scalar value is provided per element in the grid subset.

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].pitch_angle[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["runaway_electrons.ggd_fluid[:].pitch_angle[:].values", "1...N"]
    runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    runaway_electrons.ggd_fluid[:].pitch_angle[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ggd_fluid[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.global_quantities.current_tor

    Total runaway current (toroidal component)

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.energy_kinetic

    Total runaway kinetic energy

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.current_density

    Runaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_compton

    Compton source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_dreicer

    Dreicer source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_hot_tail

    Hot tail source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_total

    Total source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.ddensity_dt_tritium

    Tritium source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.density

    Runaway electrons density

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.e_field_critical

    Critical electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.e_field_dreicer

    Dreicer electric field (parallel to magnetic field)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.energy_density_kinetic

    Runaways kinetic mean energy density

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.momentum_critical_avalanche

    Critical momentum for avalanche, Compton and tritium

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.momentum_critical_hot_tail

    Critical momentum for hot tail

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.global_quantities.volume_average.pitch_angle

    Average pitch angle of the runaways distribution function (v_parallel/|v|)

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element"]
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["runaway_electrons.grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    runaway_electrons.grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    runaway_electrons.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    runaway_electrons.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    runaway_electrons.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    runaway_electrons.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    runaway_electrons.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    runaway_electrons.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    runaway_electrons.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    runaway_electrons.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_avalanche_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_avalanche_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.momentum_critical_avalanche_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_hot_tail_definition.description

    Verbose description

    • Data Type: STR_0D
    runaway_electrons.momentum_critical_hot_tail_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    runaway_electrons.momentum_critical_hot_tail_definition.name

    Short string identifier

    • Data Type: STR_0D
    runaway_electrons.profiles_1d[:].current_density

    Runaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_compton

    Compton source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_dreicer

    Dreicer source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_hot_tail

    Hot tail source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_total

    Total source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].ddensity_dt_tritium

    Tritium source of runaway electrons

    • Units: m^-3.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].density

    Runaway electrons density

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].e_field_critical

    Critical electric field

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].e_field_dreicer

    Dreicer electric field (parallel to B)

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].energy_density_kinetic

    Runaways kinetic mean energy density

    • Units: J.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].momentum_critical_avalanche

    Critical momentum for avalanche, Compton and tritium

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].momentum_critical_hot_tail

    Critical momentum for hot tail

    • Units: kg.m^-1.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].pitch_angle

    Average pitch angle of the runaways distribution function (v_parallel/|v|)

    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    runaway_electrons.profiles_1d[:].transport_perpendicular.d

    Effective diffusivity

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].transport_perpendicular.flux

    Flux

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.profiles_1d[:].transport_perpendicular.v

    Effective convection

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.profiles_1d[:].grid.rho_tor_norm"]
    runaway_electrons.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    runaway_electrons.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["runaway_electrons.time"]
    runaway_electrons.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    sawteeth.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.code.library[:].name

    Name of software

    • Data Type: STR_0D
    sawteeth.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    sawteeth.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.code.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.crash_trigger

    Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N as follows. 1: crash triggered by the ideal kink criterion; 2: crash triggered by the ideal kink criterion including kinetic effects from fast particles; 31: crash triggered by the resistive kink criterion (meeting necessary conditions for reconnection); 32: crash triggered by the resistive kink criterion (resistive kink mode is unstable). The distinction between 31 and 32 only indicates whether (31) or (32) was the last criterion to be satisfied

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.magnetic_shear_q1

    Magnetic shear at surface q = 1, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_crash_time

    Time at which the previous sawtooth crash occured

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_crash_trigger

    Previous crash trigger. Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N

    • Data Type: INT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.previous_period

    Previous sawtooth period

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_inversion

    Normalised toroidal flux coordinate at inversion radius

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_mixing

    Normalised toroidal flux coordinate at mixing radius

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.diagnostics.rho_tor_norm_q1

    Normalised toroidal flux coordinate at surface q = 1

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    sawteeth.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    sawteeth.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    sawteeth.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    sawteeth.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    sawteeth.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    sawteeth.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    sawteeth.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    sawteeth.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    sawteeth.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    sawteeth.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    sawteeth.profiles_1d[:].conductivity_parallel

    Parallel conductivity

    • Units: ohm^-1.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].e_field_parallel

    Parallel electric field = average(E.B) / B0, where CoreProfiles/VacuumToroidal_Field/ B0

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    sawteeth.profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_bootstrap

    Bootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_non_inductive

    Non-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_ohmic

    Ohmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_tor

    Total toroidal current density = average(J_Tor/R) / average(1/R)

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].j_total

    Total parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0

    • Units: A/m^2
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].magnetic_shear

    Magnetic shear, defined as rhotor/q . dq/drhotor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].momentum_tor

    Total plasma toroidal momentum, summed over ion species and electrons

    • Units: kg.m/s
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_e

    Electron density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_e_fast

    Density of fast (non-thermal) electrons

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e

    Electron pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e_fast_parallel

    Fast (non-thermal) electron parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_e_fast_perpendicular

    Fast (non-thermal) electron perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total

    Total ion pressure (sum over the ion species)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total_fast_parallel

    Fast (non-thermal) total ion (sum over the ion species) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].p_i_total_fast_perpendicular

    Fast (non-thermal) total ion (sum over the ion species) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].phi

    Toroidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_parallel

    Total parallel pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_perpendicular

    Total perpendicular pressure (electrons+ions, thermal+non-thermal)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].pressure_thermal

    Thermal pressure (electrons+ions)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].psi_star_post_crash

    Psi* = psi - phi, after the sawtooth crash

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].psi_star_pre_crash

    Psi* = psi - phi, just before the sawtooth crash

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].q

    Safety factor

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].t_e

    Electron temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].t_i_average

    Ion temperature (averaged on charge states and ion species)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    sawteeth.profiles_1d[:].zeff

    Effective charge

    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.profiles_1d[:].grid.rho_tor_norm"]
    sawteeth.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    sawteeth.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["sawteeth.time"]
    sawteeth.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    soft_x_rays.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].aperture[:].outline.x1"]
    soft_x_rays.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].brightness.data

    Data

    • Units: W.m^-2.sr^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "soft_x_rays.channel[:].brightness.time"]
    soft_x_rays.channel[:].brightness.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    soft_x_rays.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].detector.outline.x1"]
    soft_x_rays.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].energy_band[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].energy_band[:].energies"]
    soft_x_rays.channel[:].energy_band[:].energies

    Array of discrete energy values inside the band

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].energy_band[:].lower_bound

    Lower bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    soft_x_rays.channel[:].energy_band[:].upper_bound

    Upper bound of the energy band

    • Units: eV
    • Data Type: FLT_0D
    soft_x_rays.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    soft_x_rays.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].filter_window[:].outline.x1"]
    soft_x_rays.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["soft_x_rays.channel[:].filter_window[:].wavelengths"]
    soft_x_rays.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    soft_x_rays.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    soft_x_rays.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    soft_x_rays.channel[:].power.data

    Data

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "soft_x_rays.channel[:].power.time"]
    soft_x_rays.channel[:].power.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    soft_x_rays.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["soft_x_rays.channel[:].validity_timed.time"]
    soft_x_rays.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    soft_x_rays.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.code.library[:].name

    Name of software

    • Data Type: STR_0D
    soft_x_rays.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    soft_x_rays.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["soft_x_rays.time"]
    soft_x_rays.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.code.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    soft_x_rays.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    soft_x_rays.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    soft_x_rays.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    soft_x_rays.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    soft_x_rays.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    soft_x_rays.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    soft_x_rays.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    soft_x_rays.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    soft_x_rays.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    soft_x_rays.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    soft_x_rays.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    soft_x_rays.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.bucked

    Flag indicating if center stack elements bucked to one another

    • Data Type: INT_0D
    solid_mechanics.center_stack.displacement.oh

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.displacement.pl

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.displacement.tf

    Radial displacement

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.grid.r_oh

    Radial coordinate in OH layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.grid.r_pl

    Radial coordinate in plug layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.grid.r_tf

    Radial coordinate in TF layer

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    solid_mechanics.center_stack.noslip

    Flag indicating if center stack elements are not allowed to slip with respect to one another

    • Data Type: INT_0D
    solid_mechanics.center_stack.plug

    Flag indicating if center stack has a plug

    • Data Type: INT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.oh

    Change in shape for OH structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.pl

    Change in shape for plug structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.poisson_ratio.tf

    Change in shape for TF structural material due to applied stress

    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.oh

    Maximum stress OH can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.pl

    Maximum stress plug can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.yield_strength.tf

    Maximum stress TF can withstand without permanent deformation

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.oh

    Stiffness of OH structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.pl

    Stiffness of plug structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.properties.young_modulus.tf

    Stiffness of TF structural material

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.oh

    Average axial stress for OH layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.pl

    Average axial stress for plug layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.axial.tf

    Average axial stress for TF layer in center stack

    • Units: Pa
    • Data Type: FLT_0D
    solid_mechanics.center_stack.stress.hoop.oh

    Hoop stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.hoop.pl

    Hoop stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.hoop.tf

    Hoop stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.stress.radial.oh

    Radial stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.radial.pl

    Radial stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.radial.tf

    Radial stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.center_stack.stress.vonmises.oh

    Von Mises stresses OH layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_oh"]
    solid_mechanics.center_stack.stress.vonmises.pl

    Von Mises stresses plug layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_pl"]
    solid_mechanics.center_stack.stress.vonmises.tf

    Von Mises stresses TF layer

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["solid_mechanics.center_stack.grid.r_tf"]
    solid_mechanics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.channel[:].a

    Atomic mass measured by this channel

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spectrometer_mass.channel[:].current

    Collected current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].photomultiplier_voltage

    Voltage applied to the photomultiplier

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].pressure_partial

    Partial pressure (calibrated data)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.channel[:].time

    Timebase for the dynamic nodes of this channel

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.channel[:].validity

    Indicator of the validity of the data. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning)

    • Data Type: INT_0D
    spectrometer_mass.channel[:].validity_timed

    Indicator of the validity of the data for each time slice. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Means problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning.)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_mass.channel[:].time"]
    spectrometer_mass.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_mass.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_mass.time"]
    spectrometer_mass.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.identifier

    ID of the spectrometer

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_mass.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_mass.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_mass.name

    Name of the spectrometer

    • Data Type: STR_0D
    spectrometer_mass.residual_spectrum[:].a

    Array of atomic masses

    • Units: Atomic Mass Unit
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_mass.residual_spectrum[:].current

    Collected current

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_mass.residual_spectrum[:].a"]
    spectrometer_mass.residual_spectrum[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_mass.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].aperture[:].outline.x1"]
    spectrometer_uv.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].detector.outline.x1"]
    spectrometer_uv.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].detector_layout.detector_dimensions

    Total detector dimension in each direction (horizontal, vertical)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_layout.pixel_dimensions

    Pixel dimension in each direction (horizontal, vertical)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_layout.pixel_n

    Number of pixels in each direction (horizontal, vertical)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_uv.channel[:].detector_position_parameter.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].detector_position_parameter.time"]
    spectrometer_uv.channel[:].detector_position_parameter.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.curvature_radius

    Curvature radius of the spherical grating

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.groove_density

    Number of grooves per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.curvature_radius

    Curvature radius of the image surface

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.image_field.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].grating.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].grating.outline.x1"]
    spectrometer_uv.channel[:].grating.summit.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.summit.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.summit.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].grating.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].grating.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].intensity_spectrum.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_uv.channel[:].intensity_spectrum.time"]
    spectrometer_uv.channel[:].intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.amplitude_parameter

    Amplitude of the line of sight position parameter oscillation (in case moving_mode/index = 1)

    • Units: mixed
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.channel[:].line_of_sight.moving_mode.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.channel[:].line_of_sight.period

    Period of the line of sight oscillation (in case moving_mode/index = 1)

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].line_of_sight.position_parameter.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.position_parameter.time"]
    spectrometer_uv.channel[:].line_of_sight.position_parameter.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.second_point.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].line_of_sight.second_point.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].line_of_sight.second_point.time"]
    spectrometer_uv.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    spectrometer_uv.channel[:].processed_line[:].intensity.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].processed_line[:].intensity.time"]
    spectrometer_uv.channel[:].processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].processed_line[:].radiance.time"]
    spectrometer_uv.channel[:].processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].wavelengths"]
    spectrometer_uv.channel[:].radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_uv.channel[:].radiance_spectral.time"]
    spectrometer_uv.channel[:].radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].supply_high_voltage[:].object

    Name of the object connected to the power supply

    • Data Type: STR_0D
    spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time"]
    spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_uv.channel[:].validity_timed.data

    Data

    • Data Type: INT_2D
    • Coordinates: ["spectrometer_uv.channel[:].wavelengths", "spectrometer_uv.channel[:].validity_timed.time"]
    spectrometer_uv.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.channel[:].wavelength_calibration.gain

    Gain

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].wavelength_calibration.offset

    Offset

    • Units: m
    • Data Type: FLT_0D
    spectrometer_uv.channel[:].wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_uv.channel[:].wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_uv.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_uv.time"]
    spectrometer_uv.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.etendue

    Etendue (geometric extent) of the optical system

    • Units: m^2.sr
    • Data Type: FLT_0D
    spectrometer_uv.etendue_method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_uv.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_uv.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_uv.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_uv.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].active_spatial_resolution[:].width.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].aperture[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].aperture[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].aperture[:].outline.x1"]
    spectrometer_visible.channel[:].aperture[:].radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].aperture[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].detector.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].detector.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector.outline.x1"]
    spectrometer_visible.channel[:].detector.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.circular.ellipticity

    Ellipticity

    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.circular.radius

    Radius of the circle

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].detector_image.geometry_type

    Type of geometry used to describe the image (1:'outline', 2:'circular')

    • Data Type: INT_0D
    spectrometer_visible.channel[:].detector_image.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector_image.outline.r"]
    spectrometer_visible.channel[:].detector_image.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].detector_image.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].detector_image.outline.r"]
    spectrometer_visible.channel[:].etendue

    Etendue (geometric extent) of the channel's optical system

    • Units: m^2.str
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].etendue_method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].etendue_method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].etendue_method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1"]
    spectrometer_visible.channel[:].fibre_bundle.fibre_radius

    Radius of a single fibre

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1"]
    spectrometer_visible.channel[:].fibre_bundle.geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.circular.ellipticity

    Ellipticity

    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.circular.radius

    Radius of the circle

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].fibre_image.geometry_type

    Type of geometry used to describe the image (1:'outline', 2:'circular')

    • Data Type: INT_0D
    spectrometer_visible.channel[:].fibre_image.outline.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_image.outline.r"]
    spectrometer_visible.channel[:].fibre_image.outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].fibre_image.outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].fibre_image.outline.r"]
    spectrometer_visible.channel[:].filter_spectrometer.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_central

    Central wavelength of the filter

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_width

    Filter transmission function width (at 90% level)

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.output_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time"]
    spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time"]
    spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.photon_count.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.photon_count.time"]
    spectrometer_visible.channel[:].filter_spectrometer.photon_count.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].filter_spectrometer.sensitivity

    Photoelectric sensitivity of the detector. This is the conversion factor from the received power on the detector into electric voltage depending on the wavelength

    • Units: V.W^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].filter_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].filter_spectrometer.wavelengths

    Array of wavelengths for radiance calibration

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3

    Third dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].geometry_matrix.interpolated.data

    Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector or head of an optic fibre). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi

    • Units: m^-2
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.phi

    Toroidal angle (oriented counter-clockwise when viewing from above) of interpolation knots

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.r

    Major radius of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.interpolated.z

    Height of interpolation knots

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.interpolated.r"]
    spectrometer_visible.channel[:].geometry_matrix.voxel_map

    Voxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.

    • Data Type: INT_3D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1", "spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2", "spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3"]
    spectrometer_visible.channel[:].geometry_matrix.voxels_n

    Number of voxels defined in the voxel_map.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].geometry_matrix.with_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.with_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.with_reflections.data"]
    spectrometer_visible.channel[:].geometry_matrix.without_reflections.data

    The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].geometry_matrix.without_reflections.voxel_indices

    List of voxel indices (defined in the voxel map) used in the sparse data array

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].geometry_matrix.without_reflections.data"]
    spectrometer_visible.channel[:].grating_spectrometer.exposure_time

    Exposure time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.grating

    Number of grating lines per unit length

    • Units: m^-1
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.instrument_function

    Array of Gaussian widths and amplitudes which as a sum make up the instrument function. The instrument function is the shape that would be measured by a grating spectrometer if perfectly monochromatic line emission would be used as input. F(lambda) = 1 / sqrt (2*pi) * sum( instrumentfunction(1,i) / instrumentfunction(2,i) ) * exp( -lambda^2 / (2 * instrumentfunction(2,i)^2) ) ), whereby sum( instrumentfunction(1,i) ) = 1

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.data

    Data

    • Units: (counts) s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time"]
    spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.data

    Data

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].label

    String identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.data

    Data

    • Units: m^-2.s^-1.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].wavelength_central

    Central wavelength of the processed line

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration

    Radiance calibration

    • Units: m^-3.sr^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].grating_spectrometer.wavelengths"]
    spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration_date

    Date of the radiance calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.data

    Data

    • Units: (photons).m^-2.s^-1.sr^-1.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time"]
    spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].grating_spectrometer.slit_width

    Width of the slit (placed in the object focal plane)

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.gain

    Gain

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.offset

    Offset

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration_date

    Date of the wavelength calibration (yyyymmdd)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].grating_spectrometer.wavelengths

    Measured wavelengths

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_fraction

    Fraction of cold neutrals for this isotope (ncoldneutrals/(ncoldneutrals+nhotneutrals))

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_temperature

    Temperature of cold neutrals for this isotope

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].density_ratio

    Ratio of the density of neutrals of this isotope over the summed neutral densities of all other isotopes described in the ../isotope array

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_fraction

    Fraction of hot neutrals for this isotope (nhotneutrals/(ncoldneutrals+nhotneutrals))

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_temperature

    Temperature of hot neutrals for this isotope

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.isotope[:].time"]
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].label

    String identifying the species (H, D, T, He3, He4)

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.isotope[:].time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.method.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.method.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.method.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].isotope_ratios.signal_to_noise

    Log10 of the ratio of the powers in two bands, one with the spectral lines of interest (signal) the other without spectral lines (noise).

    • Units: dB
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.time"]
    spectrometer_visible.channel[:].isotope_ratios.time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].isotope_ratios.validity

    Indicator of the validity of the isotope ratios for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].isotope_ratios.validity_timed

    Indicator of the validity of the isotope ratios as a function of time (0 means valid, negative values mean non-valid)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].isotope_ratios.time"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].light_collection_efficiencies.positions.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].light_collection_efficiencies.values

    Values of the light collection efficiencies

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].light_collection_efficiencies.positions.r"]
    spectrometer_visible.channel[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    spectrometer_visible.channel[:].object_observed

    Main object observed by the channel

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].back_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].front_surface.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].optical_element[:].geometry.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1"]
    spectrometer_visible.channel[:].optical_element[:].geometry.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.extinction_coefficient

    Extinction coefficient (for metal)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.refractive_index

    Refractive index (for metal and dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.roughness

    Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.transmission_coefficient

    Transmission coefficient (for dielectric)

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths"]
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths

    Wavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficient

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].optical_element[:].thickness

    Distance between frontsurface and backsurface along the X3 vector

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].optical_element[:].type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].optical_element[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].optical_element[:].type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].polarization_spectroscopy.b_field_modulus

    Modulus of the magnetic field (always positive, irrespective of the sign convention for the B-field direction), obtained from Zeeman effect fit

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_r

    Lower Hybrid electric field component in the major radius direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_tor

    Lower Hybrid electric field component in the toroidal direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_z

    Lower Hybrid electric field component in the vertical direction

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.n_e

    Electron density, obtained from Stark broadening fit

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.temperature_cold_neutrals

    Fit of cold neutrals temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.temperature_hot_neutrals

    Fit of hot neutrals temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.time

    Timebase for dynamic quantities at this level of the data structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].polarization_spectroscopy.velocity_cold_neutrals

    Projection of the cold neutral velocity along the line of sight, positive when going from first point to second point of the line of sight

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarization_spectroscopy.velocity_hot_neutrals

    Projection of the hot neutral velocity along the line of sight, positive when going from first point to second point of the line of sight

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarization_spectroscopy.time"]
    spectrometer_visible.channel[:].polarizer.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].polarizer.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.channel[:].polarizer.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_visible.channel[:].polarizer.outline.x1"]
    spectrometer_visible.channel[:].polarizer.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_visible.channel[:].polarizer_active

    Indicator of whether a polarizer is present and active in the optical system (set to 1 in this case, set to 0 or leave empty ottherwise)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.channel[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.channel[:].type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.channel[:].validity

    Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

    • Data Type: INT_0D
    spectrometer_visible.channel[:].validity_timed.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.channel[:].validity_timed.time"]
    spectrometer_visible.channel[:].validity_timed.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_visible.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_visible.time"]
    spectrometer_visible.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.detector_layout

    Layout of the detector grid employed. Ex: '4x16', '4x32', '1x18'

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_visible.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_visible.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_visible.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_visible.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].aperture.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.geometry_type

    Type of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].aperture.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].aperture.outline.x1"]
    spectrometer_x_ray_crystal.channel[:].aperture.radius

    Radius of the circle, used only if geometry_type = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.surface

    Surface of the detector/aperture, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x1_width

    Full width of the aperture in the X1 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x2_width

    Full width of the aperture in the X2 direction, used only if geometry_type = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.centre

    Centre (in terms of absolute wavelength) of instrument function

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.intensity

    Scaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detector

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.scale

    Scale of Lorentzian instrument function (full width at half height)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.sigma

    Standard deviation of Gaussian instrument function

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.values

    Explicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a binned pixel of the detector, gives the detector pixel output in counts/seconds.

    • Units: sr.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths

    Array of wavelengths on which the instrument function is defined

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].bin[:].wavelength

    Wavelength of incoming photons on each horizontal pixel of this bin.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].bin[:].z_pixel_range

    Vertical pixel index range indicating the corresponding binned detector area

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.camera_dimensions

    Total camera dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.identifier

    ID of the camera

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_dimensions

    Pixel dimension in each direction (x1, x2)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixel_position.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    spectrometer_x_ray_crystal.channel[:].camera.pixels_n

    Number of pixels in each direction (x1, x2)

    • Data Type: INT_1D
    • Coordinates: ["1...2"]
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.angle_bragg

    Bragg angle of the crystal

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.cut

    Miller indices characterizing the cut of the crystal (can be of length 3 or 4)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.identifier

    ID of the object

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].crystal.outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].crystal.outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].crystal.outline.x1"]
    spectrometer_x_ray_crystal.channel[:].crystal.radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.surface

    Surface of the object, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.thickness

    Thickness of the crystal

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.wavelength_bragg

    Bragg wavelength of the crystal

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x1_width

    Full width of the object in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x2_width

    Full width of the object in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].detection_efficiency

    Probability of detection of a photon impacting the detector as a function of its energy

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].energies"]
    spectrometer_x_ray_crystal.channel[:].energies

    Array of energy values for tabulation of the detection efficiency

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].energy_bound_lower

    Lower energy bound for the photon detection, for each pixel (horizontal, vertical)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].energy_bound_upper

    Upper energy bound for the photon detection, for each pixel (horizontal, vertical)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].exposure_time

    Exposure time of the measurement

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].identifier

    ID of the filter

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].photon_absorption

    Probability of absorbing a photon passing through the filter as a function of its wavelength

    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].surface

    Surface of the filter, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].thickness

    Thickness of the filter window

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_lower

    Lower bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_upper

    Upper bound of the filter wavelength range

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths

    Array of wavelength values

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_width

    Full width of the filter in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_width

    Full width of the filter in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].frame[:].counts_bin_n

    Number of counts detected on each pixel/bin of the binned frame during one exposure time

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].bin"]
    spectrometer_x_ray_crystal.channel[:].frame[:].counts_n

    Number of counts detected on each pixel of the frame during one exposure time

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].frame[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.centre

    Centre (in terms of absolute wavelength) of instrument function

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.intensity

    Scaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detector

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.scale

    Scale of Lorentzian instrument function (full width at half height)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.sigma

    Standard deviation of Gaussian instrument function

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].instrument_function.values

    Explicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a pixel of the detector, gives the detector pixel output in counts/seconds.

    • Units: sr.m
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames", "spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths"]
    spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths

    Array of wavelengths on which the instrument function is defined

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.data

    Data

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.data

    Data

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.data

    Data

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time

    Timebase for the dynamic nodes of this probe located at this level of the IDS structure

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.data

    Data

    • Units: m.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity

    Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity_timed

    Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].centre.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].identifier

    ID of the object

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].material.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1

    Positions along x1 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x2

    Positions along x2 axis

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1"]
    spectrometer_x_ray_crystal.channel[:].reflector[:].radius

    Radius of the circle, used only if geometry_type/index = 2

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].surface

    Surface of the object, derived from the above geometric data

    • Units: m^2
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_curvature

    Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x1_width

    Full width of the object in the X1 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_curvature

    Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x2_width

    Full width of the object in the X2 direction, used only if geometry_type/index = 3

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.channel[:].wavelength_frames

    Wavelength of incoming photons on each pixel of the frames, mainly varying accross the horizontal dimension of the frame. However a 2D map of the wavelength is given since it is not constant vertically due to the elliptical curvature of the photon iso-surfaces

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "spectrometer_x_ray_crystal.channel[:].z_frames"]
    spectrometer_x_ray_crystal.channel[:].z_frames

    Height of the observed zone at the focal plane in the plasma, corresponding to the vertical dimension of the frame

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spectrometer_x_ray_crystal.time"]
    spectrometer_x_ray_crystal.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spectrometer_x_ray_crystal.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spectrometer_x_ray_crystal.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spectrometer_x_ray_crystal.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    spectrometer_x_ray_crystal.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spi.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.code.library[:].name

    Name of software

    • Data Type: STR_0D
    spi.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    spi.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["spi.time"]
    spi.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.code.repository

    URL of software repository

    • Data Type: STR_0D
    spi.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    spi.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    spi.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    spi.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    spi.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    spi.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    spi.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spi.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    spi.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    spi.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    spi.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    spi.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    spi.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    spi.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    spi.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    spi.injector[:].fragment[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].fragment[:].species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].fragment[:].velocity_r

    Major radius component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].velocity_tor

    Toroidal component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].velocity_z

    Vertical component of the fragment velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragment[:].volume

    Volume of the fragment

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragmentation_gas.atoms_n

    Total number of atoms of the gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.flow_rate

    Flow rate of the gas at the injector exit

    • Units: atoms.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].fragmentation_gas.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.species[:].fraction

    Atomic fraction of the species

    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].fragmentation_gas.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].fragmentation_gas.temperature

    Gas temperature

    • Units: K
    • Data Type: FLT_0D
    spi.injector[:].identifier

    Identifier of the injector

    • Data Type: STR_0D
    spi.injector[:].injection_direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].injection_direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].injection_direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].name

    Name of the injector

    • Data Type: STR_0D
    spi.injector[:].optical_pellet_diagnostic.position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].optical_pellet_diagnostic.time_arrival

    Arrival time at the optical pellet diagnostic, for each object

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    spi.injector[:].pellet.core.atoms_n

    Total number of atoms of desublimated gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].pellet.core.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].pellet.core.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.diameter

    Pellet diameter

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].pellet.length

    Pellet length (cylindrical pellet)

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].pellet.position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.shell.atoms_n

    Total number of atoms of desublimated gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].density

    Density of the species

    • Units: atoms.m^-3
    • Data Type: FLT_0D
    spi.injector[:].pellet.shell.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].pellet.shell.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].pellet.velocity_r

    Major radius component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.velocity_shatter

    Norm of the velocity of the centre of mass of the pellet right before shattering

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].pellet.velocity_tor

    Toroidal component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].pellet.velocity_z

    Vertical component of the velocity of the centre of mass of the pellet

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].propellant_gas.atoms_n

    Total number of atoms of the gas

    • Units: atoms
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.flow_rate

    Flow rate of the gas at the injector exit

    • Units: atoms.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["spi.time"]
    spi.injector[:].propellant_gas.species[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.species[:].fraction

    Atomic fraction of the species

    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.species[:].label

    String identifying the species (e.g. H, D, T, ...)

    • Data Type: STR_0D
    spi.injector[:].propellant_gas.species[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    spi.injector[:].propellant_gas.temperature

    Gas temperature

    • Units: K
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.angle_major

    Angle between the cone direction and unitvectormajor

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.angle_minor

    Angle between the cone direction and unitvectorminor

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.direction.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.origin.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_major.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.x

    Component along X axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.y

    Component along Y axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shatter_cone.unit_vector_minor.z

    Component along Z axis

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shattering_angle

    Impact (or grazing) angle of the pellet with the shattering element. It is the complementary of the incidence angle with the element surface at the shattering location

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].shattering_position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    spi.injector[:].time_shatter

    Arrival time at the shattering unit

    • Units: s
    • Data Type: FLT_0D
    spi.injector[:].time_trigger

    Time of trigger request to the power supply according to the DMS sequence

    • Units: s
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_r

    Major radius component of the velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_tor

    Toroidal component of the velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.injector[:].velocity_mass_centre_fragments_z

    Vertical component of the velocity velocity of the centre of mass of the fragments at the shattering cone origin

    • Units: m.s^-1
    • Data Type: FLT_0D
    spi.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    spi.shatter_cone_definition.description

    Verbose description

    • Data Type: STR_0D
    spi.shatter_cone_definition.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    spi.shatter_cone_definition.name

    Short string identifier

    • Data Type: STR_0D
    spi.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    stability.all_cleared

    True (1) if all stability limits are cleared, otherwise False (0)

    • Data Type: INT_1D
    • Coordinates: ["stability.time"]
    stability.collection[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    stability.collection[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    stability.collection[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    stability.model[:].cleared

    True (1) if a given stability limit is cleared, otherwise False (0)

    • Data Type: INT_1D
    • Coordinates: ["stability.time"]
    stability.model[:].fraction

    Fraction of limit

    • Data Type: FLT_1D
    • Coordinates: ["stability.time"]
    stability.model[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    stability.model[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    stability.model[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    stability.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    summary.boundary.distance_inner_outer_separatrices.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.distance_inner_outer_separatrices.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.elongation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.elongation.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.gap_limiter_wall.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.gap_limiter_wall.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.geometric_axis_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.geometric_axis_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.geometric_axis_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.geometric_axis_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.magnetic_axis_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.magnetic_axis_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.magnetic_axis_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.magnetic_axis_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.minor_radius.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.minor_radius.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_configuration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_configuration.value

    Value

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_inner_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_inner_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_outer_r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_outer_r.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.strike_point_outer_z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.strike_point_outer_z.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.triangularity_lower.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.triangularity_lower.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.triangularity_upper.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.triangularity_upper.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.type.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.type.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.x_point_main.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.boundary.x_point_main.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.boundary.x_point_main.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.code.library[:].name

    Name of software

    • Data Type: STR_0D
    summary.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    summary.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.code.repository

    URL of software repository

    • Data Type: STR_0D
    summary.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.configuration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.configuration.value

    Value

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.current_runaways.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.current_runaways.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.energy_thermal.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.ip.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.ip.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.exponential.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.exponential.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_20_80.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.linear_20_80.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.x1

    User-defined parameter, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.decay_times.t_e_volume_average.linear_custom.x2

    User-defined value, see description of linear_custom

    • Data Type: FLT_0D
    summary.disruption.mitigation_valve.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.mitigation_valve.value

    Value

    • Data Type: INT_0D
    summary.disruption.time.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.time_half_ip.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time_half_ip.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.time_radiated_power_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.time_radiated_power_max.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.disruption.vertical_displacement.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.disruption.vertical_displacement.value

    Value

    • Data Type: INT_0D
    summary.elms.frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.elms.frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.elms.type.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.elms.type.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_power_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_power_total.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dd.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dd.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.dt.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.dt.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.beam_beam.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.beam_beam.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.beam_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.beam_thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.thermal.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.neutron_rates.tt.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.neutron_rates.tt.total.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.fusion.power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.fusion.power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ammonia.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ammonia_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.argon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.beryllium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.bottom.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.carbon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.deuterium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ethane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.ethylene.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.helium_3.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.helium_4.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.hydrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_accumulated.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.krypton.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.lithium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane_carbon_13.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.methane_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.midplane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.neon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.nitrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.oxygen.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.propane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.silane.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.top.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.total.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.tritium.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_accumulated.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_accumulated.xenon.value

    Value

    • Units: electrons
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_prefill.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ammonia.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ammonia_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.argon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.beryllium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.bottom.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.carbon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.deuterium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ethane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.ethylene.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.helium_3.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.helium_4.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.hydrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_prefill.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.krypton.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.lithium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane_carbon_13.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.methane_deuterated.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.midplane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.neon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.nitrogen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.oxygen.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.propane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.silane.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.top.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.total.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.tritium.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_prefill.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_prefill.xenon.value

    Value

    • Units: electrons
    • Data Type: FLT_0D
    summary.gas_injection_rates.ammonia.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ammonia.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ammonia_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ammonia_deuterated.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.argon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.beryllium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.bottom.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.bottom.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.carbon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.deuterium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ethane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ethane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.ethylene.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.ethylene.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.helium_3.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.helium_4.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.hydrogen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.impurity_seeding.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.impurity_seeding.value

    Value

    • Data Type: INT_0D
    summary.gas_injection_rates.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.krypton.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.lithium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane_carbon_13.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane_carbon_13.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.methane_deuterated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.methane_deuterated.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.midplane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.midplane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.neon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.nitrogen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.oxygen.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.propane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.propane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.silane.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.silane.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.top.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.total.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.tritium.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.gas_injection_rates.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.gas_injection_rates.xenon.value

    Value

    • Units: electrons.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.b0.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.b0.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_pol.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_pol_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_pol_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_norm.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_norm_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_norm_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.beta_tor_thermal_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.beta_tor_thermal_norm.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_alignment.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_alignment.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_bootstrap.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_bootstrap.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_non_inductive.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_non_inductive.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.current_ohm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.current_ohm.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.denergy_diamagnetic_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.denergy_diamagnetic_dt.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.denergy_thermal_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.denergy_thermal_dt.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_b_field_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_b_field_pol.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_diamagnetic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_diamagnetic.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_electrons_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_electrons_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_fast_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_fast_parallel.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_fast_perpendicular.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_fast_perpendicular.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_ion_total_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_ion_total_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_mhd.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_thermal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_thermal.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.energy_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.energy_total.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.fusion_fluence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.fusion_fluence.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.fusion_gain.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.fusion_gain.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.greenwald_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.greenwald_fraction.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.h_98.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.h_98.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.h_mode.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.h_mode.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.ip.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.ip.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.li.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.li.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.li_mhd.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.li_mhd.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_bremsstrahlung.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_bremsstrahlung.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_line.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_line.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_loss.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_loss.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_ohm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_ohm.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated_inside_lcfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated_inside_lcfs.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_radiated_outside_lcfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_radiated_outside_lcfs.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_steady.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_steady.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.power_synchrotron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.power_synchrotron.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.psi_external_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.psi_external_average.value

    Value

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.q_95.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.q_95.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.r0.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.r0.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.global_quantities.ratio_tau_helium_fuel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.ratio_tau_helium_fuel.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.resistance.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.resistance.value

    Value

    • Units: ohm
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_energy.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_energy.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_energy_98.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_energy_98.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_helium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_helium.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.tau_resistive.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.tau_resistive.value

    Value

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.v_loop.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.v_loop.value

    Value

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.global_quantities.volume.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.global_quantities.volume.value

    Value

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].angle_pol.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].angle_pol.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].angle_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].angle_tor.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].harmonic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].harmonic.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].polarisation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].polarisation.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ec[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ec[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].e_field_plus_minus_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].e_field_plus_minus_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].harmonic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].harmonic.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].k_perpendicular.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].k_perpendicular.value

    Value

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].n_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].n_tor.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].phase.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].phase.value

    Value

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.ic[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.ic[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].energy_fast.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].energy_fast.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].frequency.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].frequency.value

    Value

    • Units: Hz
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].n_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].n_parallel.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.lh[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.lh[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].angle.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].angle.value

    Value

    • Units: rad
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].beam_current_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].beam_current_fraction.value

    Value

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "summary.time"]
    summary.heating_current_drive.nbi[:].beam_power_fraction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].beam_power_fraction.value

    Value

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "summary.time"]
    summary.heating_current_drive.nbi[:].current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].direction.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].direction.value

    Value

    • Data Type: INT_0D
    summary.heating_current_drive.nbi[:].energy.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].energy.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].position.phi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.phi.value

    Value

    • Units: rad
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].position.r.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.r.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].position.z.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].position.z.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].power.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].power.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].power_launched.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].power_launched.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.nbi[:].species.a.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.a.value

    Value

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].species.label.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.label.value

    Value

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.z_n.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].species.z_n.value

    Value

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    summary.heating_current_drive.nbi[:].tangency_radius.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.nbi[:].tangency_radius.value

    Value

    • Units: m
    • Data Type: FLT_0D
    summary.heating_current_drive.power_additional.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_additional.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_ec.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_ec.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_ic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_ic.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_ec.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_ec.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_ic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_ic.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_lh.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_lh.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_nbi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_nbi.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_nbi_co_injected_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_nbi_co_injected_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_launched_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_launched_total.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_lh.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_lh.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.heating_current_drive.power_nbi.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.heating_current_drive.power_nbi.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    summary.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    summary.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    summary.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    summary.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    summary.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    summary.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    summary.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    summary.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    summary.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    summary.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    summary.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    summary.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    summary.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    summary.kicks.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.kicks.occurrence.value

    Value

    • Data Type: INT_0D
    summary.limiter.material.description

    Verbose description

    • Data Type: STR_0D
    summary.limiter.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.limiter.material.name

    Short string identifier

    • Data Type: STR_0D
    summary.line_average.dn_e_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.dn_e_dt.value

    Value

    • Units: m^-3.s-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.isotope_fraction_hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.isotope_fraction_hydrogen.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.meff_hydrogenic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.meff_hydrogenic.value

    Value

    • Units: amu
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.line_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.line_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].flux_expansion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].flux_expansion.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].name.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].name.value

    Value

    • Data Type: STR_0D
    summary.local.divertor_target[:].power_flux_peak.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].power_flux_peak.value

    Value

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.divertor_target[:].zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.divertor_target[:].zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.itb.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.itb.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.flux_expansion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.flux_expansion.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.name.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.name.value

    Value

    • Data Type: STR_0D
    summary.local.limiter.power_flux_peak.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.power_flux_peak.value

    Value

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.limiter.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.limiter.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.b_field.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.b_field.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.magnetic_axis.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.magnetic_axis.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.pedestal.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.pedestal.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.effective_helical_ripple.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.effective_helical_ripple.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.iota.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.iota.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.r_eff_norm_2_3.plateau_factor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.r_eff_norm_2_3.plateau_factor.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.e_field_parallel.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.e_field_parallel.value

    Value

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.magnetic_shear.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.magnetic_shear.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.momentum_tor.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.momentum_tor.value

    Value

    • Units: kg.m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under globalquantities/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.position.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.q.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.q.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.argon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.beryllium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.carbon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.deuterium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.helium_3.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.helium_4.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.hydrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.iron.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.krypton.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.lithium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.neon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.nitrogen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.oxygen.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.tritium.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.tungsten.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.velocity_tor.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.velocity_tor.xenon.value

    Value

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.local.separatrix_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.local.separatrix_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.magnetic_shear_flag.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.magnetic_shear_flag.value

    Value

    • Data Type: INT_0D
    summary.midplane.description

    Verbose description

    • Data Type: STR_0D
    summary.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.midplane.name

    Short string identifier

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_average.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_pol_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.b_field_tor_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_average.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.beta_pol_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.coulomb_factor_pedestal_top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.coulomb_factor_pedestal_top.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.energy_thermal_pedestal_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.energy_thermal_pedestal_electron.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.energy_thermal_pedestal_ion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.energy_thermal_pedestal_ion.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.d_dpsi_norm.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.d_dpsi_norm_max.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.offset.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_height.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.n_e.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.n_e.separatrix.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.nustar_pedestal_top_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.nustar_pedestal_top_electron.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.parameters

    Parameters of the fit

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...5"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.offset.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_height.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.pressure_electron.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.pressure_electron.separatrix.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_magnetic_axis.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.rhostar_pedestal_top_electron_magnetic_axis.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.d_dpsi_norm.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.d_dpsi_norm_max.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.offset.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_height.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.t_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.t_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.linear.volume_inside_pedestal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.linear.volume_inside_pedestal.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.alpha_electron_pedestal_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_average.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_pol_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_hfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.b_field_tor_pedestal_top_lfs.value

    Value

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_average.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.beta_pol_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.coulomb_factor_pedestal_top.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.coulomb_factor_pedestal_top.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_electron.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_ion.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.energy_thermal_pedestal_ion.value

    Value

    • Units: J
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.offset.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_height.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.n_e.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.n_e.separatrix.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.nustar_pedestal_top_electron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.nustar_pedestal_top_electron.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.parameters

    Parameters of the fit

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...5"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.offset.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_height.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.pressure_electron.separatrix.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.pressure_electron.separatrix.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_hfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_hfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_lfs.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_lfs.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_magnetic_axis.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.rhostar_pedestal_top_electron_magnetic_axis.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.alpha_experimental.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.alpha_experimental.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_critical.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.alpha_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.t_e_pedestal_top_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_hager.t_e_pedestal_top_critical.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_critical.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_ratio.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.alpha_ratio.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.t_e_pedestal_top_critical.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.stability.bootstrap_current_sauter.t_e_pedestal_top_critical.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.d_dpsi_norm_max_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.offset.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.offset.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_height.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_height.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_position.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_position.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.t_e.pedestal_width.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.t_e.pedestal_width.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pedestal_fits.mtanh.volume_inside_pedestal.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pedestal_fits.mtanh.volume_inside_pedestal.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.pellets.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.pellets.occurrence.value

    Value

    • Data Type: INT_0D
    summary.plasma_duration.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.plasma_duration.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.rmps.occurrence.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.rmps.occurrence.value

    Value

    • Data Type: INT_0D
    summary.runaways.current.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.runaways.current.value

    Value

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.runaways.particles.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.runaways.particles.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.heat_flux_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.heat_flux_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.heat_flux_i_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.heat_flux_i_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.n_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.n_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.n_i_total_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.n_i_total_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.power_radiated.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.power_radiated.value

    Value

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.pressure_neutral.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.pressure_neutral.value

    Value

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.t_e_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.t_e_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.scrape_off_layer.t_i_average_decay_length.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.scrape_off_layer.t_i_average_decay_length.value

    Value

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.stationary_phase_flag.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.stationary_phase_flag.value

    Value

    • Data Type: INT_1D
    • Coordinates: ["summary.time"]
    summary.tag.comment

    Any comment describing the content of the tagged list of entries

    • Data Type: STR_0D
    summary.tag.name

    Name of the tag

    • Data Type: STR_0D
    summary.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    summary.time_breakdown.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.time_breakdown.value

    Value

    • Units: s
    • Data Type: FLT_0D
    summary.time_width

    In case the time-dependent quantities of this IDS are averaged over a time interval, this node is the width of this time interval (empty otherwise). By convention, the time interval starts at time-time_width and ends at time.

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.dn_e_dt.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.dn_e_dt.value

    Value

    • Units: m^-3.s-1
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.isotope_fraction_hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.isotope_fraction_hydrogen.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.meff_hydrogenic.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.meff_hydrogenic.value

    Value

    • Units: amu
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_e.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.argon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.argon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.beryllium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.beryllium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.carbon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.carbon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.deuterium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.deuterium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.helium_3.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.helium_3.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.helium_4.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.helium_4.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.hydrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.hydrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.iron.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.iron.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.krypton.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.krypton.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.lithium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.lithium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.neon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.neon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.nitrogen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.nitrogen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.oxygen.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.oxygen.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.tritium.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.tritium.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.tungsten.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.tungsten.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i.xenon.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i.xenon.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.n_i_total.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.n_i_total.value

    Value

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.t_e.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.t_e.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.t_i_average.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.t_i_average.value

    Value

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.volume_average.zeff.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.volume_average.zeff.value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["summary.time"]
    summary.wall.evaporation.source

    Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)

    • Data Type: STR_0D
    summary.wall.evaporation.value

    Value

    • Data Type: STR_0D
    summary.wall.material.description

    Verbose description

    • Data Type: STR_0D
    summary.wall.material.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    summary.wall.material.name

    Short string identifier

    • Data Type: STR_0D
    temporary.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.code.library[:].name

    Name of software

    • Data Type: STR_0D
    temporary.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    temporary.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["temporary.time"]
    temporary.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.code.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.constant_float0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float0d[:].value

    Value

    • Data Type: FLT_0D
    temporary.constant_float1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float1d[:].value

    Value

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.constant_float2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float2d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    temporary.constant_float3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float3d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "1...N"]
    temporary.constant_float4d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float4d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float4d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float4d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N"]
    temporary.constant_float5d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float5d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float5d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float5d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_5D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N"]
    temporary.constant_float6d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_float6d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_float6d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_float6d[:].value

    Value

    • Units: mixed
    • Data Type: FLT_6D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N", "1...N"]
    temporary.constant_integer0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer0d[:].value

    Value

    • Data Type: INT_0D
    temporary.constant_integer1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer1d[:].value

    Value

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    temporary.constant_integer2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer2d[:].value

    Value

    • Data Type: INT_2D
    • Coordinates: ["1...N", "1...N"]
    temporary.constant_integer3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_integer3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_integer3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_integer3d[:].value

    Value

    • Data Type: INT_3D
    • Coordinates: ["1...N", "1...N", "1...N"]
    temporary.constant_string0d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_string0d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_string0d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_string0d[:].value

    Value

    • Data Type: STR_0D
    temporary.constant_string1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.constant_string1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.constant_string1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.constant_string1d[:].value

    Value

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float1d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["temporary.dynamic_float1d[:].value.time"]
    temporary.dynamic_float1d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float2d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "temporary.dynamic_float2d[:].value.time"]
    temporary.dynamic_float2d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float3d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "temporary.dynamic_float3d[:].value.time"]
    temporary.dynamic_float3d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float4d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float4d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float4d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float4d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_4D
    • Coordinates: ["1...N", "1...N", "1...N", "temporary.dynamic_float4d[:].value.time"]
    temporary.dynamic_float4d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float5d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float5d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float5d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float5d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_5D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "temporary.dynamic_float5d[:].value.time"]
    temporary.dynamic_float5d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_float6d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_float6d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_float6d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_float6d[:].value.data

    Data

    • Units: mixed
    • Data Type: FLT_6D
    • Coordinates: ["1...N", "1...N", "1...N", "1...N", "1...N", "temporary.dynamic_float6d[:].value.time"]
    temporary.dynamic_float6d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer1d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer1d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer1d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer1d[:].value.data

    Data

    • Data Type: INT_1D
    • Coordinates: ["temporary.dynamic_integer1d[:].value.time"]
    temporary.dynamic_integer1d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer2d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer2d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer2d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer2d[:].value.data

    Data

    • Data Type: INT_2D
    • Coordinates: ["1...N", "temporary.dynamic_integer2d[:].value.time"]
    temporary.dynamic_integer2d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.dynamic_integer3d[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    temporary.dynamic_integer3d[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.dynamic_integer3d[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    temporary.dynamic_integer3d[:].value.data

    Data

    • Data Type: INT_3D
    • Coordinates: ["1...N", "1...N", "temporary.dynamic_integer3d[:].value.time"]
    temporary.dynamic_integer3d[:].value.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    temporary.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    temporary.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    temporary.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    temporary.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    temporary.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    temporary.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    temporary.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    temporary.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    temporary.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    temporary.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    temporary.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    temporary.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    temporary.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    temporary.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    temporary.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    temporary.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.b_field_tor_vacuum_r.data

    Data

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["tf.b_field_tor_vacuum_r.time"]
    tf.b_field_tor_vacuum_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.code.library[:].name

    Name of software

    • Data Type: STR_0D
    tf.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    tf.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["tf.time"]
    tf.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.code.repository

    URL of software repository

    • Data Type: STR_0D
    tf.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.coil[:].conductor[:].cross_section.delta_phi

    Toroidal angles (relative to a reference point)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].cross_section.delta_r"]
    tf.coil[:].conductor[:].cross_section.delta_r

    Major radii (relative to a reference point)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].cross_section.delta_z

    Heights (relative to a reference point)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].cross_section.delta_r"]
    tf.coil[:].conductor[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].current.time"]
    tf.coil[:].conductor[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.centres.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.centres.r"]
    tf.coil[:].conductor[:].elements.centres.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.centres.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.centres.r"]
    tf.coil[:].conductor[:].elements.end_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.end_points.r"]
    tf.coil[:].conductor[:].elements.end_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.end_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.end_points.r"]
    tf.coil[:].conductor[:].elements.intermediate_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.intermediate_points.r"]
    tf.coil[:].conductor[:].elements.intermediate_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.intermediate_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.intermediate_points.r"]
    tf.coil[:].conductor[:].elements.names

    Name or description of every element

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.start_points.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.start_points.r"]
    tf.coil[:].conductor[:].elements.start_points.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].conductor[:].elements.start_points.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.start_points.r"]
    tf.coil[:].conductor[:].elements.types

    Type of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circle

    • Data Type: INT_1D
    • Coordinates: ["tf.coil[:].conductor[:].elements.names"]
    tf.coil[:].conductor[:].resistance

    conductor resistance

    • Units: Ohm
    • Data Type: FLT_0D
    tf.coil[:].conductor[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].conductor[:].voltage.time"]
    tf.coil[:].conductor[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].current.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].current.time"]
    tf.coil[:].current.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coil[:].identifier

    Alphanumeric identifier of coil used for convenience

    • Data Type: STR_0D
    tf.coil[:].name

    Name of the coil

    • Data Type: STR_0D
    tf.coil[:].resistance

    Coil resistance

    • Units: Ohm
    • Data Type: FLT_0D
    tf.coil[:].turns

    Number of total turns in a toroidal field coil. May be a fraction when describing the coil connections.

    • Data Type: FLT_0D
    tf.coil[:].voltage.data

    Data

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["tf.coil[:].voltage.time"]
    tf.coil[:].voltage.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.coils_n

    Number of coils around the torus, in case is_periodic = 1

    • Data Type: INT_0D
    tf.delta_b_field_tor_vacuum_r.data

    Data

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["tf.delta_b_field_tor_vacuum_r.time"]
    tf.delta_b_field_tor_vacuum_r.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_r[:].values", "1...N"]
    tf.field_map[:].a_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_tor[:].values", "1...N"]
    tf.field_map[:].a_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].a_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].a_field_z[:].values", "1...N"]
    tf.field_map[:].a_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].a_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].a_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_r[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_r[:].values", "1...N"]
    tf.field_map[:].b_field_r[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_r[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_r[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_tor[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_tor[:].values", "1...N"]
    tf.field_map[:].b_field_tor[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_tor[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_tor[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].b_field_z[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: FLT_2D
    • Coordinates: ["tf.field_map[:].b_field_z[:].values", "1...N"]
    tf.field_map[:].b_field_z[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    tf.field_map[:].b_field_z[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    tf.field_map[:].b_field_z[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element"]
    tf.field_map[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element"]
    tf.field_map[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["tf.field_map[:].grid.grid_subset[:].element", "1...N", "1...N"]
    tf.field_map[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    tf.field_map[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    tf.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    tf.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    tf.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    tf.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    tf.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    tf.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    tf.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    tf.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    tf.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    tf.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    tf.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    tf.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    tf.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    tf.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    tf.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    tf.is_periodic

    Flag indicating whether coils are described one by one in the coil() structure (flag=0) or whether the coil structure represents only coils having different characteristics (flag = 1, n_coils must be filled in that case). In the latter case, the coil() sequence is repeated periodically around the torus.

    • Data Type: INT_0D
    tf.latency

    Upper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.

    • Units: s
    • Data Type: FLT_0D
    tf.r0

    Reference major radius of the device (from the official description of the device). This node is the placeholder for this official machine description quantity (typically the middle of the vessel at the equatorial midplane, although the exact definition may depend on the device)

    • Units: m
    • Data Type: FLT_0D
    tf.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].delta_position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].delta_position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].delta_position.time

    Time for the R,Z,phi coordinates

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].delta_position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].delta_position.time"]
    thomson_scattering.channel[:].distance_separatrix_midplane.data

    Data

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].distance_separatrix_midplane.time"]
    thomson_scattering.channel[:].distance_separatrix_midplane.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].identifier

    ID of the channel

    • Data Type: STR_0D
    thomson_scattering.channel[:].n_e.data

    Data

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].n_e.time"]
    thomson_scattering.channel[:].n_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.channel[:].name

    Name of the channel

    • Data Type: STR_0D
    thomson_scattering.channel[:].position.phi

    Toroidal angle (oriented counter-clockwise when viewing from above)

    • Units: rad
    • Data Type: FLT_0D
    thomson_scattering.channel[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_0D
    thomson_scattering.channel[:].position.z

    Height

    • Units: m
    • Data Type: FLT_0D
    thomson_scattering.channel[:].t_e.data

    Data

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["thomson_scattering.channel[:].t_e.time"]
    thomson_scattering.channel[:].t_e.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    thomson_scattering.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.code.library[:].name

    Name of software

    • Data Type: STR_0D
    thomson_scattering.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    thomson_scattering.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["thomson_scattering.time"]
    thomson_scattering.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.code.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.machine

    Name of the experimental device to which this data is related

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.pulse

    Pulse number

    • Data Type: INT_0D
    thomson_scattering.equilibrium_id.data_entry.pulse_type

    Type of the data entry, e.g. "pulse", "simulation", ...

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.data_entry.run

    Run number

    • Data Type: INT_0D
    thomson_scattering.equilibrium_id.data_entry.user

    Username

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.name

    IDS name

    • Data Type: STR_0D
    thomson_scattering.equilibrium_id.occurrence

    IDS occurrence

    • Data Type: INT_0D
    thomson_scattering.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    thomson_scattering.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    thomson_scattering.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    thomson_scattering.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    thomson_scattering.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    thomson_scattering.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    thomson_scattering.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    thomson_scattering.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    thomson_scattering.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    thomson_scattering.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    thomson_scattering.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    thomson_scattering.latency

    Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

    • Units: s
    • Data Type: FLT_0D
    thomson_scattering.midplane.description

    Verbose description

    • Data Type: STR_0D
    thomson_scattering.midplane.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    thomson_scattering.midplane.name

    Short string identifier

    • Data Type: STR_0D
    thomson_scattering.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].current.value

    Value of the boundary condition. For ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.rho_tor_norm

    Position, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.

    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.value

    Value of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.boundary_conditions_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].current[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element", "1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].values

    List of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.boundary_conditions_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].name

    Name of software

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    transport_solver_numerics.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["transport_solver_numerics.time"]
    transport_solver_numerics.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.code.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].current.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].current.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].current.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].electrons.energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].electrons.particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].energy_ion_total.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.equations[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.convergence.time_step.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.convergence.time_step.time"]
    transport_solver_numerics.convergence.time_step.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d2psi_drho_tor2

    Second derivative of the poloidal flux profile with respect to the toroidal flux coordinate

    • Units: Wb.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dt.n_i_total_over_n_e

    Ratio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dt.pressure_ion_total

    Total thermal ion pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].d_dvolume_drho_tor_dt

    Partial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinate

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_drho_tor

    Derivative of the poloidal flux profile with respect to the toroidal flux coordinate

    • Units: Wb.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt

    Derivative of the poloidal flux profile with respect to time

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt_cphi

    Derivative of the poloidal flux profile with respect to time, at constant toroidal flux

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].dpsi_dt_crho_tor_norm

    Derivative of the poloidal flux profile with respect to time, at constant normalised toroidal flux coordinate

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].drho_tor_dt

    Partial derivative of the toroidal flux coordinate profile with respect to time

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.derivatives_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density_fast

    Density of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure

    Pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_pol

    Poloidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_tor

    Toroidal velocity (average over charge states when multiple charge states are considered)

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density_fast

    Density of fast (non-thermal) particles

    • Units: m^-3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure

    Pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_parallel

    Fast (non-thermal) parallel pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_perpendicular

    Fast (non-thermal) perpendicular pressure

    • Units: Pa
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_pol

    Poloidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_tor

    Toroidal velocity

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].is_neutral

    Flag specifying if this state corresponds to a neutral (1) or not (0)

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].ion[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    transport_solver_numerics.derivatives_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    transport_solver_numerics.primary_coordinate.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.primary_coordinate.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.primary_coordinate.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.restart_files[:].descriptions

    Descriptions of the restart files

    • Data Type: STR_1D
    • Coordinates: ["transport_solver_numerics.restart_files[:].names"]
    transport_solver_numerics.restart_files[:].names

    Names of the restart files

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.restart_files[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.solver.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].name

    Name of the control parameter

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].value

    Value of the control parameter

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].name

    Name of the control parameter

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].value

    Value of the control parameter

    • Units: mixed
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].d_dvolume_drho_tor_dt

    Partial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinate

    • Units: m^2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].drho_tor_dt

    Partial derivative of the toroidal flux coordinate profile with respect to time

    • Units: m.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].position

    Position, in terms of the primary coordinate, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed (in case of a single boundary condition).

    • Units: mixed
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].value

    Value of the boundary condition. For type/index = 1 to 3, only the first position in the vector is used. For type/index = 5, all three positions are used, meaning respectively a1, a2, a3.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...3"]
    transport_solver_numerics.solver_1d[:].equation[:].coefficient[:].profile

    Radial profile of the numerical coefficient

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].computation_mode.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.expression

    Expression used by the solver to calculate the relative deviation

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.value

    Value of the relative deviation

    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].equation[:].convergence.iterations_n

    Number of iterations carried out in the convergence loop

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d2_dr2

    Second order radial derivative with respect to the primary coordinate

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dr

    Radial derivative with respect to the primary coordinate

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt

    Time derivative

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cphi

    Derivative with respect to time, at constant toroidal flux (for current diffusion equation)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cr

    Derivative with respect to time, at constant primary coordinate coordinate (for current diffusion equation)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.description

    Verbose description

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.name

    Short string identifier

    • Data Type: STR_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.ion_index

    If the primary quantity is related to a ion species, index of the corresponding species in the coreprofiles/profiles1d/ion array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.neutral_index

    If the primary quantity is related to a neutral species, index of the corresponding species in the coreprofiles/profiles1d/neutral array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.profile

    Profile of the primary quantity

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.state_index

    If the primary quantity is related to a particular state (of an ion or a neutral species), index of the corresponding state in the coreprofiles/profiles1d/ion (or neutral)/state array

    • Data Type: INT_0D
    transport_solver_numerics.solver_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    transport_solver_numerics.solver_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.solver_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.solver_1d[:].grid.rho_tor_norm"]
    transport_solver_numerics.solver_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    transport_solver_numerics.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step.time"]
    transport_solver_numerics.time_step.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step_average.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step_average.time"]
    transport_solver_numerics.time_step_average.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.time_step_min.data

    Data

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time_step_min.time"]
    transport_solver_numerics.time_step_min.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    transport_solver_numerics.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["transport_solver_numerics.time"]
    transport_solver_numerics.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    turbulence.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.code.library[:].name

    Name of software

    • Data Type: STR_0D
    turbulence.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    turbulence.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["turbulence.time"]
    turbulence.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.code.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.grid_2d[:].dim1

    First dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    turbulence.grid_2d[:].dim2

    Second dimension values

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    turbulence.grid_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    turbulence.grid_2d_type.description

    Verbose description

    • Data Type: STR_0D
    turbulence.grid_2d_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    turbulence.grid_2d_type.name

    Short string identifier

    • Data Type: STR_0D
    turbulence.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    turbulence.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    turbulence.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    turbulence.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    turbulence.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    turbulence.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    turbulence.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    turbulence.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    turbulence.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    turbulence.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    turbulence.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    turbulence.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    turbulence.profiles_2d[:].electrons.density

    Density (thermal+non-thermal)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].electrons.density_thermal

    Density of thermal particles

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].electrons.temperature

    Temperature

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    turbulence.profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].ion[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    turbulence.profiles_2d[:].ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    turbulence.profiles_2d[:].ion[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radius

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].density

    Density (thermal+non-thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].neutral[:].density_thermal

    Density (thermal) (sum over charge states when multiple charge states are considered)

    • Units: m^-3
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    turbulence.profiles_2d[:].neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    turbulence.profiles_2d[:].neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    turbulence.profiles_2d[:].neutral[:].label

    String identifying ion (e.g. H+, D+, T+, He+2, C+, ...)

    • Data Type: STR_0D
    turbulence.profiles_2d[:].neutral[:].temperature

    Temperature (average over charge states when multiple charge states are considered)

    • Units: eV
    • Data Type: FLT_2D
    • Coordinates: ["turbulence.grid_2d[:].dim1", "turbulence.grid_2d[:].dim2"]
    turbulence.profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    turbulence.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.code.library[:].name

    Name of software

    • Data Type: STR_0D
    wall.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    wall.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["wall.time"]
    wall.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.code.repository

    URL of software repository

    • Data Type: STR_0D
    wall.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.description_2d[:].limiter.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].limiter.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].limiter.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].limiter.unit[:].component_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].component_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].limiter.unit[:].component_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].identifier

    Identifier of this unit. Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : ic_antenna/a1/bumpers refers to the bumpers of the a1 IC antenna

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].name

    Name of the limiter unit

    • Data Type: STR_0D
    wall.description_2d[:].limiter.unit[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].limiter.unit[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].limiter.unit[:].outline.r"]
    wall.description_2d[:].limiter.unit[:].phi_extensions

    Simplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    wall.description_2d[:].limiter.unit[:].resistivity

    Resistivity of the limiter unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].mobile.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].mobile.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].mobile.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].mobile.unit[:].closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].mobile.unit[:].name

    Name of the mobile unit

    • Data Type: STR_0D
    wall.description_2d[:].mobile.unit[:].outline[:].r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].mobile.unit[:].outline[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_2d[:].mobile.unit[:].outline[:].z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].mobile.unit[:].outline[:].r"]
    wall.description_2d[:].mobile.unit[:].phi_extensions

    Simplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "1...N"]
    wall.description_2d[:].mobile.unit[:].resistivity

    Resistivity of the mobile unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].vessel.type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_2d[:].vessel.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_2d[:].vessel.type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].annular.centreline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.centreline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.centreline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.centreline.r"]
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.outline_inner.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.outline_inner.r"]
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].annular.outline_outer.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.outline_outer.r"]
    wall.description_2d[:].vessel.unit[:].annular.resistivity

    Resistivity of the vessel unit

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].annular.thickness

    Thickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].annular.centreline.r"]
    wall.description_2d[:].vessel.unit[:].element[:].j_tor.data

    Data

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].element[:].j_tor.time"]
    wall.description_2d[:].vessel.unit[:].element[:].j_tor.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].element[:].name

    Name of the block element

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].element[:].outline.closed

    Flag identifying whether the contour is closed (1) or open (0)

    • Data Type: INT_0D
    wall.description_2d[:].vessel.unit[:].element[:].outline.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_2d[:].vessel.unit[:].element[:].outline.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_2d[:].vessel.unit[:].element[:].outline.r"]
    wall.description_2d[:].vessel.unit[:].element[:].resistance

    Resistance of the block element

    • Units: Ohm
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].element[:].resistivity

    Resistivity of the block element

    • Units: ohm.m
    • Data Type: FLT_0D
    wall.description_2d[:].vessel.unit[:].identifier

    Identifier of the unit

    • Data Type: STR_0D
    wall.description_2d[:].vessel.unit[:].name

    Name of the unit

    • Data Type: STR_0D
    wall.description_ggd[:].component[:].identifiers

    Identifiers of the components (described in the various gridsubsets). Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : icantenna/a1/bumpers refers to the bumpers of the a1 IC antenna

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].component[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].component[:].type[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].component[:].type[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].component[:].type[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].a_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].a_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].a_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].a_field[:].r"]
    wall.description_ggd[:].ggd[:].a_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].a_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: T.m
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].a_field[:].r"]
    wall.description_ggd[:].ggd[:].a_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T.m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].e_field[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].e_field[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].e_field[:].r"]
    wall.description_ggd[:].ggd[:].e_field[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].e_field[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].e_field[:].r"]
    wall.description_ggd[:].ggd[:].e_field[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].j_total[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].j_total[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].j_total[:].r

    Component along the major radius axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].r_coefficients

    Interpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].toroidal

    Toroidal component, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].j_total[:].r"]
    wall.description_ggd[:].ggd[:].j_total[:].toroidal_coefficients

    Interpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].j_total[:].z

    Component along the height axis, one scalar value is provided per element in the grid subset.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].ggd[:].j_total[:].r"]
    wall.description_ggd[:].ggd[:].j_total[:].z_coefficients

    Interpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m^-2.s^-1
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m^-2.s^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].phi_potential[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].phi_potential[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].phi_potential[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].power_density[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: W.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].power_density[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].power_density[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].power_density[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].power_density[:].values

    One scalar value is provided per element in the grid subset.

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].psi[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].psi[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].psi[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].psi[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].psi[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].label

    String identifying ion (e.g. H, D, T, He, C, D2, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].multiple_states_flag

    Multiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].neutral_index

    Index of the corresponding neutral species in the ../../neutral array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_max

    Maximum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_min

    Minimum Z of the charge state bundle

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].ion_index

    Index of the corresponding ion species in the ../../ion array

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].label

    String identifying neutral (e.g. H, D, T, He, C, ...)

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].multiple_states_flag

    Multiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values

    One scalar value is provided per element in the grid subset.

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].label

    String identifying state

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    wall.description_ggd[:].ggd[:].resistivity[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: Ohm.m
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].resistivity[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].resistivity[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].resistivity[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].resistivity[:].values

    One scalar value is provided per element in the grid subset.

    • Units: Ohm.m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].temperature[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: K
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].temperature[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].temperature[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].temperature[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].temperature[:].values

    One scalar value is provided per element in the grid subset.

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].ggd[:].v_biasing[:].values", "1...N"]
    wall.description_ggd[:].ggd[:].v_biasing[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].ggd[:].v_biasing[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["wall.description_ggd[:].grid_ggd[:].grid_subset[:].element", "1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].grid_ggd[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].material[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].material[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.descriptions

    Verbose description

    • Data Type: STR_1D
    • Coordinates: ["wall.description_ggd[:].material[:].grid_subset[:].identifiers.names"]
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.indices

    Integer identifiers (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_1D
    • Coordinates: ["wall.description_ggd[:].material[:].grid_subset[:].identifiers.names"]
    wall.description_ggd[:].material[:].grid_subset[:].identifiers.names

    Short string identifiers

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].material[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["wall.description_ggd[:].thickness[:].grid_subset[:].values", "1...N"]
    wall.description_ggd[:].thickness[:].grid_subset[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    wall.description_ggd[:].thickness[:].grid_subset[:].values

    One scalar value is provided per element in the grid subset.

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.description_ggd[:].thickness[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    wall.description_ggd[:].type.description

    Verbose description

    • Data Type: STR_0D
    wall.description_ggd[:].type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.description_ggd[:].type.name

    Short string identifier

    • Data Type: STR_0D
    wall.first_wall_enclosed_volume

    Volume available to gas or plasma enclosed by the first wall contour

    • Units: m^3
    • Data Type: FLT_0D
    wall.first_wall_power_flux_peak.data

    Data

    • Units: W.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["wall.first_wall_power_flux_peak.time"]
    wall.first_wall_power_flux_peak.time

    Time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.first_wall_surface_area

    First wall surface area

    • Units: m^2
    • Data Type: FLT_0D
    wall.global_quantities.current_tor

    Toroidal current flowing in the vacuum vessel

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.gas_puff

    Gas puff rate (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.particle_flux_from_plasma

    Particle flux from the plasma (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.particle_flux_from_wall

    Particle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), in equivalent electrons

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.electrons.power_inner_target

    Electron power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.power_outer_target

    Electron power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.electrons.pumping_speed

    Pumped particle flux (in equivalent electrons)

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.global_quantities.neutral[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].gas_puff

    Gas puff rate for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].incident_species[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].incident_species[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    wall.global_quantities.neutral[:].incident_species[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    wall.global_quantities.neutral[:].incident_species[:].energies

    Array of energies of this incident species, on which the sputteringphysicalcoefficient is tabulated

    • Units: eV
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    wall.global_quantities.neutral[:].incident_species[:].label

    String identifying the incident species (e.g. H, D, CD4, ...)

    • Data Type: STR_0D
    wall.global_quantities.neutral[:].incident_species[:].sputtering_chemical_coefficient

    Effective coefficient of chemical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].incident_species[:].sputtering_physical_coefficient

    Effective coefficient of physical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species and for various energies (second dimension)

    • Data Type: FLT_3D
    • Coordinates: ["1...3", "wall.global_quantities.neutral[:].incident_species[:].energies", "wall.time"]
    wall.global_quantities.neutral[:].label

    String identifying the species (e.g. H, D, CD4, ...)

    • Data Type: STR_0D
    wall.global_quantities.neutral[:].particle_flux_from_plasma

    Particle flux from the plasma for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].particle_flux_from_wall

    Particle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Units: s^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].pumping_speed

    Pumped particle flux for that species

    • Units: s^-1
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.neutral[:].recycling_energy_coefficient

    Energy recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].recycling_particles_coefficient

    Particle recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)

    • Data Type: FLT_2D
    • Coordinates: ["1...3", "wall.time"]
    wall.global_quantities.neutral[:].wall_inventory

    Wall inventory, i.e. cumulated exchange of neutral species between plasma and wall from t = 0, positive if a species has gone to the wall, for that species

    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_black_body

    Black body radiated power emitted from the wall (emissivity is included)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_conducted

    Power conducted by the plasma onto the wall

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_convected

    Power convected by the plasma onto the wall

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_currents

    Power deposited on the wall due to electric currents (positive means power is deposited on the target)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_density_inner_target_max

    Maximum power density on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_density_outer_target_max

    Maximum power density on the outer target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_incident

    Total power incident on the wall. This power is split in the various physical categories listed below

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_inner_target_ion_total

    Total ion (summed over ion species) power on the inner target

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_neutrals

    Net power from neutrals on the wall (positive means power is deposited on the wall)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_radiated

    Net radiated power from plasma onto the wall (incident-reflected)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_recombination_neutrals

    Power deposited on the wall due to recombination of neutrals into a ground state (e.g. molecules)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_recombination_plasma

    Power deposited on the wall due to recombination of plasma ions

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.power_to_cooling

    Power to cooling systems

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.global_quantities.temperature

    Wall temperature

    • Units: K
    • Data Type: FLT_1D
    • Coordinates: ["wall.time"]
    wall.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    wall.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    wall.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    wall.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    wall.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    wall.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    wall.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    wall.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    wall.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    wall.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    wall.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    wall.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    wall.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    wall.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    wall.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    wall.temperature_reference.data

    Reference temperature

    • Units: K
    • Data Type: FLT_0D
    wall.temperature_reference.description

    Description of how the reference temperature is defined : for which object, at which location, ...

    • Data Type: STR_0D
    wall.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.code.library[:].name

    Name of software

    • Data Type: STR_0D
    waves.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    waves.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["waves.time"]
    waves.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.code.repository

    URL of software repository

    • Data Type: STR_0D
    waves.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.imaginary

    Imaginary part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.real

    Real part

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].electrons.power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].power

    Power absorbed along the beam by the species

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].length

    Ray/beam curvilinear length

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].phase.angle

    Rotation angle for the phase ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].phase.curvature

    Inverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)

    • Units: m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.phi

    Toroidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.psi

    Poloidal flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.theta

    Poloidal angle

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].position.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.parallel

    Normalized power flow in the direction parallel to the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.perpendicular

    Normalized power flow in the direction perpendicular to the magnetic field

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].power_initial

    Initial power in the ray/beam

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].beam_tracing[:].beam[:].spot.angle

    Rotation angle for the spot ellipse

    • Units: rad
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].spot.size

    Size of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...2", "waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r

    Wave vector component in the major radius direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r_norm

    Normalized wave vector component in the major radius direction = k_r / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor

    Wave vector component in the toroidal direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor_norm

    Normalized wave vector component in the toroidal direction = k_tor / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z

    Wave vector component in the vertical direction

    • Units: m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z_norm

    Normalized wave vector component in the vertical direction = k_z / norm(k)

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_parallel

    Parallel refractive index

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_perpendicular

    Perpendicular refractive index

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_tor

    Toroidal wave number, contains a single value if varyingntor = 0 to avoid useless repetition constant values. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive ntor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["coherent_wave[:].beam_tracing[:].beam[:].length"]
    waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.varying_n_tor

    Flag telling whether n_tor is constant along the ray path (0) or varying (1)

    • Data Type: INT_0D
    waves.coherent_wave[:].beam_tracing[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: T
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: T
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.minus[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.minus[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.normal[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.normal[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: CPX_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].e_field.plus[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_subset_index

    Index of the grid subset the data is provided on

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].e_field.plus[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: CPX_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].dimension

    Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].dimension

    Dimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].index

    Object index

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].space

    Index of the space from which that object is taken

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.jacobian

    Metric Jacobian

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_contravariant

    Contravariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_covariant

    Covariant metric tensor, given on each element of the subgrid (first dimension)

    • Units: mixed
    • Data Type: FLT_3D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element", "1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.path

    Path of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS paths

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].coordinates_type

    Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xml

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index

    Index of this (n-1)-dimensional boundary object

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours

    List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry

    Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d

    2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.

    • Units: mixed
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].measure

    Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)

    • Units: m^dimension
    • Data Type: FLT_0D
    waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].nodes

    List of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].coefficients

    Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values", "1...N"]
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_index

    Index of the grid used to represent this quantity

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_subset_index

    Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index

    • Data Type: INT_0D
    waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values

    One scalar value is provided per element in the grid subset.

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].full_wave[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].current_tor

    Wave driven toroidal current from a stand alone calculation (not consistent with other sources)

    • Units: A
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].current_tor_n_tor

    Wave driven toroidal current from a stand alone calculation (not consistent with other sources) per toroidal mode number

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].electrons.distribution_assumption

    Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].electrons.power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].electrons.power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].frequency

    Wave frequency

    • Units: Hz
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].distribution_assumption

    Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast

    Wave power absorbed by the fast particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast_n_tor

    Wave power absorbed by the fast particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal

    Wave power absorbed by the thermal particle population

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal_n_tor

    Wave power absorbed by the thermal particle population per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].global_quantities[:].power

    Total absorbed wave power

    • Units: W
    • Data Type: FLT_0D
    waves.coherent_wave[:].global_quantities[:].power_n_tor

    Absorbed wave power per toroidal mode number

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].global_quantities[:].n_tor"]
    waves.coherent_wave[:].global_quantities[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].identifier.antenna_name

    Name of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.

    • Data Type: STR_0D
    waves.coherent_wave[:].identifier.index_in_antenna

    Index of the wave (starts at 1), separating different waves generated from a single antenna.

    • Data Type: INT_0D
    waves.coherent_wave[:].identifier.type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].identifier.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].identifier.type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].current_parallel_density

    Flux surface averaged wave driven parallel current density = average(j.B) / B0, where B0 = vacuumtoroidalfield/b0.

    • Units: A.m^-2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].current_parallel_density_n_tor

    Flux surface averaged wave driven parallel current density, per toroidal mode number

    • Units: A.m^-2
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].current_tor_inside

    Wave driven toroidal current, inside a flux surface

    • Units: A
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].current_tor_inside_n_tor

    Wave driven toroidal current, inside a flux surface, per toroidal mode number

    • Units: A
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.psi_boundary

    Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].grid.psi_magnetic_axis

    Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)

    • Units: Wb
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].grid.rho_pol_norm

    Normalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))

    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.rho_tor

    Toroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS)

    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_1d[:].grid.surface

    Surface area of the toroidal flux surface

    • Units: m^2
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast

    Flux surface averaged absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast_n_tor

    Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal

    Flux surface averaged absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal_n_tor

    Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal_n_tor

    Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_1d[:].k_perpendicular

    Perpendicular wave vector, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that kperpendicular = ave(kperpendicular.powerdensity) / ave(powerdensity), for every flux surface and every toroidal number

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_1d[:].power_density

    Flux surface averaged total absorbed wave power density (electrons + ion + fast populations)

    • Units: W.m^-3
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].power_density_n_tor

    Flux surface averaged absorbed wave power density per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].power_inside

    Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density)

    • Units: W
    • Data Type: FLT_1D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm"]
    waves.coherent_wave[:].profiles_1d[:].power_inside_n_tor

    Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number

    • Units: W
    • Data Type: FLT_2D
    • Coordinates: ["waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm", "waves.coherent_wave[:].profiles_1d[:].n_tor"]
    waves.coherent_wave[:].profiles_1d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.amplitude

    Amplitude

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.phase

    Phase

    • Units: V.m^-1
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].grid.area

    Cross-sectional area of the flux surface

    • Units: m^2
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.psi

    Poloidal magnetic flux

    • Units: Wb
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.r

    Major radius

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.rho_tor

    Toroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.rho_tor_norm

    Normalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)

    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.theta_geometric

    Geometrical poloidal angle

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.theta_straight

    Straight field line poloidal angle

    • Units: rad
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].grid.type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].grid.type.name

    Short string identifier

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].grid.volume

    Volume enclosed inside the magnetic surface

    • Units: m^3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].grid.z

    Height

    • Units: m
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].a

    Mass of atom

    • Units: Atomic Mass Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].atoms_n

    Number of atoms of this element in the molecule

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].z_n

    Nuclear charge

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].label

    String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].multiple_states_flag

    Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure

    • Data Type: INT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].electron_configuration

    Configuration of atomic orbitals of this state, e.g. 1s2-2s1

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].label

    String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast

    Absorbed wave power density on the fast species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast_n_tor

    Absorbed wave power density on the fast species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal

    Absorbed wave power density on the thermal species

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal_n_tor

    Absorbed wave power density on the thermal species, per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_level

    Vibrational level (can be bundled)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_mode

    Vibrational mode of this state, e.g. "A_g". Need to define, or adopt a standard nomenclature.

    • Data Type: STR_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_max

    Maximum Z of the charge state bundle (equal to z_min if no bundle)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_min

    Minimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].ion[:].z_ion

    Ion charge (of the dominant ionisation state; lumped ions are allowed).

    • Units: Elementary Charge Unit
    • Data Type: FLT_0D
    waves.coherent_wave[:].profiles_2d[:].n_tor

    Toroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    waves.coherent_wave[:].profiles_2d[:].power_density

    Total absorbed wave power density (electrons + ion + fast populations)

    • Units: W.m^-3
    • Data Type: FLT_2D
    • Coordinates: ["1...N", "1...N"]
    waves.coherent_wave[:].profiles_2d[:].power_density_n_tor

    Absorbed wave power density per toroidal mode number

    • Units: W.m^-3
    • Data Type: FLT_3D
    • Coordinates: ["1...N", "1...N", "waves.coherent_wave[:].profiles_2d[:].n_tor"]
    waves.coherent_wave[:].profiles_2d[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    waves.coherent_wave[:].wave_solver_type.description

    Verbose description

    • Data Type: STR_0D
    waves.coherent_wave[:].wave_solver_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.coherent_wave[:].wave_solver_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    waves.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    waves.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    waves.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    waves.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    waves.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    waves.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    waves.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    waves.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    waves.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    waves.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    waves.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    waves.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    waves.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    waves.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    waves.magnetic_axis.r

    Major radius

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.magnetic_axis.z

    Height

    • Units: m
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    waves.vacuum_toroidal_field.b0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Units: T
    • Data Type: FLT_1D
    • Coordinates: ["waves.time"]
    waves.vacuum_toroidal_field.r0

    Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)

    • Units: m
    • Data Type: FLT_0D
    workflow.code.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.code.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.code.library[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.code.library[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.code.library[:].name

    Name of software

    • Data Type: STR_0D
    workflow.code.library[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.code.library[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.code.library[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.code.name

    Name of software generating IDS

    • Data Type: STR_0D
    workflow.code.output_flag

    Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.

    • Data Type: INT_1D
    • Coordinates: ["workflow.time"]
    workflow.code.parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.code.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.code.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.comment

    Any comment describing the content of this IDS

    • Data Type: STR_0D
    workflow.ids_properties.creation_date

    Date at which this data has been produced

    • Data Type: STR_0D
    workflow.ids_properties.homogeneous_time

    This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2

    • Data Type: INT_0D
    workflow.ids_properties.name

    User-defined name for this IDS occurrence

    • Data Type: STR_0D
    workflow.ids_properties.occurrence

    N/A

    • Data Type: INT_0D
    workflow.ids_properties.occurrence_type.description

    Verbose description

    • Data Type: STR_0D
    workflow.ids_properties.occurrence_type.index

    Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.

    • Data Type: INT_0D
    workflow.ids_properties.occurrence_type.name

    Short string identifier

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_get.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.infrastructure_put.version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].get_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].put_operation[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.ids_properties.plugins.node[:].readback[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.ids_properties.provenance.node[:].path

    Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.

    • Data Type: STR_0D
    workflow.ids_properties.provenance.node[:].sources

    List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.

    • Data Type: STR_1D
    • Coordinates: ["1...N"]
    workflow.ids_properties.provider

    Name of the person in charge of producing this data

    • Data Type: STR_0D
    workflow.ids_properties.version_put.access_layer

    Version of Access Layer used to PUT this IDS

    • Data Type: STR_0D
    workflow.ids_properties.version_put.access_layer_language

    Programming language of the Access Layer high level API used to PUT this IDS

    • Data Type: STR_0D
    workflow.ids_properties.version_put.data_dictionary

    Version of Data Dictionary used to PUT this IDS

    • Data Type: STR_0D
    workflow.time

    Generic time

    • Units: s
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.component[:].commit

    Unique commit reference of software

    • Data Type: STR_0D
    workflow.time_loop.component[:].description

    Short description of the software (type, purpose)

    • Data Type: STR_0D
    workflow.time_loop.component[:].name

    Name of software used

    • Data Type: STR_0D
    workflow.time_loop.component[:].parameters

    List of the code specific parameters in XML format

    • Data Type: STR_0D
    workflow.time_loop.component[:].repository

    URL of software repository

    • Data Type: STR_0D
    workflow.time_loop.component[:].version

    Unique version (tag) of software

    • Data Type: STR_0D
    workflow.time_loop.time_end

    Termination time for the workflow main time loop

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].component[:].control_float

    Array of real workflow control parameters used by this component (component specific)

    • Units: mixed
    • Data Type: FLT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.workflow_cycle[:].component[:].control_integer

    Array of integer workflow control parameters used by this component (component specific)

    • Data Type: INT_1D
    • Coordinates: ["1...N"]
    workflow.time_loop.workflow_cycle[:].component[:].execution_mode

    Component execution mode for current workflow cycle. 0 means the component is not executed and the workflow uses results from previous workflow cycle. 1 means the component is executed for this workflow cycle.

    • Data Type: INT_0D
    workflow.time_loop.workflow_cycle[:].component[:].index

    Index of the component in the ../../../component array

    • Data Type: INT_0D
    workflow.time_loop.workflow_cycle[:].component[:].time_interval_elapsed

    Simulation time interval for which this component has last computed its results

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].component[:].time_interval_request

    Simulation time interval for which this component is requested to compute its results

    • Units: s
    • Data Type: FLT_0D
    workflow.time_loop.workflow_cycle[:].time

    Time

    • Units: s
    • Data Type: FLT_0D
    diff --git a/dev/deps.html b/dev/deps.html index b16cbc616..e6ed74dac 100644 --- a/dev/deps.html +++ b/dev/deps.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub

    Ecosystem

    The FUSE project is built upon multiple Julia packages, many of which reside in the https://github.com/ProjectTorreyPines organization on GitHub.

    FUSE dependencies

    +
    GitHub

    Ecosystem

    The FUSE project is built upon multiple Julia packages, many of which reside in the https://github.com/ProjectTorreyPines organization on GitHub.

    FUSE dependencies

    diff --git a/dev/develop.html b/dev/develop.html index 2911f8e2b..96e41b610 100644 --- a/dev/develop.html +++ b/dev/develop.html @@ -132,4 +132,4 @@ eqt=dd.equilibrium.time_slice[-1] cp1d=dd.core_profiles.profiles_1d[-1] -jFUSE = IMAS.Sauter_neo2021_bootstrap(eqt, cp1d, neo_2021=True) +jFUSE = IMAS.Sauter_neo2021_bootstrap(eqt, cp1d, neo_2021=True) diff --git a/dev/examples.html b/dev/examples.html index 1dfa3de95..41d2a2829 100644 --- a/dev/examples.html +++ b/dev/examples.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub
    +
    GitHub
    diff --git a/dev/imas.html b/dev/imas.html index 8071dbb45..9e0c3c2fe 100644 --- a/dev/imas.html +++ b/dev/imas.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub
    +
    GitHub
    diff --git a/dev/index.html b/dev/index.html index 0a13bd742..b2966bcbc 100644 --- a/dev/index.html +++ b/dev/index.html @@ -24,4 +24,4 @@ journal = {arXiv}, title = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}}, year = {2024} -}

    Last update on 2024-10-21T02:41:46.827

    +}

    Last update on 2024-10-22T02:41:39.598

    diff --git a/dev/ini.html b/dev/ini.html index 9f1d8a158..6f678cb57 100644 --- a/dev/ini.html +++ b/dev/ini.html @@ -146,4 +146,4 @@ ├─ q95 ├─ coil_j_margin └─ coil_stress_margin - + diff --git a/dev/ini_details.html b/dev/ini_details.html index fd5ab56d1..1a1e31d4f 100644 --- a/dev/ini_details.html +++ b/dev/ini_details.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub
    ini.general.casename

    Sort mnemonic name of the case being run

    • Type: Entry{String}
    • Units: -
    ini.general.description

    Longer description of the case being run

    • Type: Entry{String}
    • Units: -
    ini.general.init_from

    Initialize run from

    • Type: Switch{Symbol}
    • Units: -
    • Options: ods, scalars
    ini.general.dd

    dd to initialize from

    • Type: Entry{IMASdd.dd}
    • Units: -
    ini.time.pulse_shedule_time_basis

    Time basis used to discretize the pulse schedule

    • Type: Entry{AbstractRange{Float64}}
    • Units: s
    ini.time.simulation_start

    Time at which the simulation starts

    • Type: Entry{Float64}
    • Units: s
    • Default: 0.0
    ini.ods.filename

    ODS.json file(s) from which equilibrium is loaded. Multiple comma-separated ODSs can be specified.

    • Type: Entry{String}
    • Units: -
    ini.equilibrium.B0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Type: Entry{Float64}
    • Units: T
    ini.equilibrium.R0

    Geometric genter of the plasma. NOTE: This also scales the radial build layers.

    • Type: Entry{Float64}
    • Units: m
    ini.equilibrium.Z0

    Z offset of the machine midplane

    • Type: Entry{Float64}
    • Units: m
    • Default: 0.0
    ini.equilibrium.ϵ

    Plasma inverse aspect ratio (a/R0). NOTE: This also scales the radial build layers.

    • Type: Entry{Float64}
    • Units: -
    ini.equilibrium.κ

    Plasma elongation. NOTE: If < 1.0 it defines the fraction of maximum controllable elongation estimate.

    • Type: Entry{Float64}
    • Units: -
    ini.equilibrium.tilt

    Tilt of the plasma boundary [MXH c0]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.δ

    Triangularity of the plasma boundary [MXH sin(s1)]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.ζ

    Squareness of the plasma boundary [MXH -s2]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.𝚶

    Ovality of the plasma boundary [MXH c1]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.twist

    Twist of the plasma boundary [MXH c2]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.pressure_core

    On axis pressure

    • Type: Entry{Float64}
    • Units: Pa
    ini.equilibrium.ip

    Plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Type: Entry{Float64}
    • Units: A
    ini.equilibrium.xpoints

    X-points configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: lower, upper, double, none
    ini.equilibrium.ngrid

    Resolution of the equilibrium grid

    • Type: Entry{Int64}
    • Units: -
    • Default: 129
    ini.equilibrium.field_null_surface

    ψn value of the fieldnullsurface. Disable with 0.0

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.75
    ini.equilibrium.boundary_from

    The starting r, z boundary taken from

    • Type: Switch{Symbol}
    • Units: -
    • Options: scalars, MXH_params, rz_points, ods
    ini.equilibrium.MXH_params

    Vector of MXH flats

    • Type: Entry{Vector{Float64}}
    • Units: -
    ini.equilibrium.rz_points

    RZ boundary as Vector{Vector{Float64}}} : r = rzpoints[1], z = rz_points[2]

    • Type: Entry{Vector{Vector{Float64}}}
    • Units: m
    ini.core_profiles.plasma_mode

    Plasma configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: H_mode, L_mode
    • Default: H_mode
    ini.core_profiles.w_ped

    Pedestal width expressed in fraction of ψₙ

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.05
    ini.core_profiles.ne_value

    Value based on setup method

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.ne_setting

    Way to set the electron density

    • Type: Switch{Symbol}
    • Units: -
    • Options: ne_ped, ne_line, greenwald_fraction, greenwald_fraction_ped
    ini.core_profiles.ne_sep_to_ped_ratio

    Ratio used to set the sepeartrix density based on the pedestal density

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.25
    ini.core_profiles.ne_core_to_ped_ratio

    Ratio used to set the core density based on the pedestal density

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.4
    ini.core_profiles.ne_shaping

    Density shaping factor

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.T_ratio

    Ti/Te ratio

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.T_shaping

    Temperature shaping factor

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.Te_sep

    Separatrix temperature

    • Type: Entry{Float64}
    • Units: eV
    • Default: 80.0
    ini.core_profiles.zeff

    Effective ion charge

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.rot_core

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Type: Entry{Float64}
    • Units: s^-1
    ini.core_profiles.ngrid

    Resolution of the core_profiles grid

    • Type: Entry{Int64}
    • Units: -
    • Default: 101
    ini.core_profiles.bulk

    Bulk ion species

    • Type: Entry{Symbol}
    • Units: -
    ini.core_profiles.impurity

    Impurity ion species

    • Type: Entry{Symbol}
    • Units: -
    ini.core_profiles.helium_fraction

    Helium density / electron density fraction

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.ejima

    Ejima coefficient

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.4
    ini.core_profiles.polarized_fuel_fraction

    Spin polarized fuel fraction

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.pf_active.n_coils_inside

    Number of PF coils inside of the TF

    • Type: Entry{Int64}
    • Units: -
    ini.pf_active.n_coils_outside

    Number of PF coils outside of the TF

    • Type: Entry{Int64}
    • Units: -
    ini.pf_active.technology

    PF coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.rampup.side

    Side of the vacuum vessel where the plasma is limited at breakdown

    • Type: Switch{Symbol}
    • Units: -
    • Options: hfs, lfs
    ini.rampup.ends_at

    Until when does the rampup lasts

    • Type: Entry{Float64}
    • Units: s
    ini.rampup.diverted_at

    Time at which x-point is formed and plasma can peel-off the wall

    • Type: Entry{Float64}
    • Units: s
    ini.nb_unit.1.power_launched

    Beam power

    • Type: Entry{Float64}
    • Units: W
    ini.nb_unit.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.nb_unit.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.3
    ini.nb_unit.1.beam_energy

    Beam energy

    • Type: Entry{Float64}
    • Units: eV
    ini.nb_unit.1.beam_mass

    Beam mass

    • Type: Entry{Float64}
    • Units: AU
    • Default: 2.0
    ini.nb_unit.1.toroidal_angle

    Toroidal angle of injection

    • Type: Entry{Float64}
    • Units: rad
    ini.nb_unit.1.efficiency_conversion

    Conversion efficiency of electric power to neutral beam power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.nb_unit.1.efficiency_transmission

    Transmission efficiency of neutral beam from source to port

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ec_launcher.1.power_launched

    EC launched power

    • Type: Entry{Float64}
    • Units: W
    ini.ec_launcher.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.5
    ini.ec_launcher.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.025
    ini.ec_launcher.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ec_launcher.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.pellet_launcher.1.frequency

    Frequency of pellets launched

    • Type: Entry{Float64}
    • Units: Hz
    ini.pellet_launcher.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.5
    ini.pellet_launcher.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.25
    ini.pellet_launcher.1.shape

    The pellet geometry

    • Type: Switch{Symbol}
    • Units: -
    • Options: spherical, cylindrical, rectangular
    • Default: spherical
    ini.pellet_launcher.1.species

    Pellet species

    • Type: Switch{Symbol}
    • Units: -
    • Options: H, D, T, DT, C, Ne
    ini.pellet_launcher.1.size

    Vector of geometric dimensions describing the pellet size for a given shape (spherical: [r], cylindrical: [d, l], rectangular: [x,y,z])

    • Type: Entry{Vector{Float64}}
    • Units: m
    ini.ic_antenna.1.power_launched

    IC launched power

    • Type: Entry{Float64}
    • Units: W
    ini.ic_antenna.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.ic_antenna.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.1
    ini.ic_antenna.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ic_antenna.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ic_antenna.1.efficiency_coupling

    Coupling efficiency of launched microwave power to the plasma

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.power_launched

    LH launched power

    • Type: Entry{Float64}
    • Units: W
    ini.lh_antenna.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.8
    ini.lh_antenna.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.05
    ini.lh_antenna.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.efficiency_coupling

    Coupling efficiency of launched microwave power to the plasma

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.hcd.power_scaling_cost_function

    EC, IC, LH, NB power optimization cost function, takes dd as input. Eg. dd -> (1.0 - IMAS.tauethermal(dd) / IMAS.taueh98(dd))

    • Type: Entry{Function}
    • Units: -
    ini.build.layers.1.name

    Name of the layer

    • Type: Entry{String}
    • Units: -
    ini.build.layers.1.thickness

    Relative thickness of the layer (layers actual thickness is scaled to match plasma R0)

    • Type: Entry{Float64}
    • Units: -
    ini.build.layers.1.material

    Material of the layer

    • Type: Switch{Symbol}
    • Units: -
    • Options: tungsten, aluminum, graphite, nbti, flibe, water, plasma, lithium_lead, nb3sn_iter, nb3sn, vacuum, rebco, steel, nb3sn_kdemo, copper
    ini.build.layers.1.shape

    Shape of the layer

    • Type: Switch{IMAS.BuildLayerShape}
    • Units: -
    • Options: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc
    ini.build.layers.1.type

    Type of the layer

    • Type: Switch{IMAS.BuildLayerType}
    • Units: -
    • Options: blanket, cryostat, gap, vessel, tf, oh, shield, port, wall, plasma, divertor
    ini.build.layers.1.side

    Side of the layer

    • Type: Switch{IMAS.BuildLayerSide}
    • Units: -
    • Options: hfs, in, lfs, out, lhfs
    ini.build.plasma_gap

    Fraction of vacuum gap between first wall and plasma separatrix in radial build

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.1
    ini.build.symmetric

    Is the build up-down symmetric

    • Type: Entry{Bool}
    • Units: -
    ini.build.divertors

    Divertors configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: lower, upper, double, none, from_x_points
    • Default: from_x_points
    ini.build.n_first_wall_conformal_layers

    Number of layers that are conformal to the first wall

    • Type: Entry{Int64}
    • Units: -
    • Default: 1
    ini.center_stack.bucked

    Flag for bucked boundary conditions between TF and OH (and center plug, if present)

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.center_stack.noslip

    Flag for no slip conditions between TF and OH (and center plug, if present)

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.center_stack.plug

    Flag for center plug

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.tf.n_coils

    Number of TF coils

    • Type: Entry{Int64}
    • Units: -
    ini.tf.shape

    Shape of the TF coils

    • Type: Switch{IMAS.BuildLayerShape}
    • Units: -
    • Options: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc
    ini.tf.ripple

    Fraction of toroidal field ripple evaluated at the outermost radius of the plasma chamber

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.01
    ini.tf.technology

    TF coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.oh.n_coils

    Number of OH coils

    • Type: Entry{Int64}
    • Units: -
    ini.oh.technology

    OH coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.bop.cycle_type

    Thermal cycle type

    • Type: Switch{Symbol}
    • Units: -
    • Options: rankine, brayton
    • Default: rankine
    ini.requirements.power_electric_net

    Net electric power generated by the fusion power plant

    • Type: Entry{Float64}
    • Units: W
    ini.requirements.flattop_duration

    Duration of the flattop (use Inf for steady-state)

    • Type: Entry{Float64}
    • Units: s
    ini.requirements.log10_flattop_duration

    Log10 value of the duration of the flattop (use Inf for steady-state). Preferred over flattop_duration for optimization studies.

    • Type: Entry{Float64}
    • Units: log10(s)
    ini.requirements.tritium_breeding_ratio

    Tritium breeding ratio of the whole plant

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.cost

    Total FPP cost

    • Type: Entry{Float64}
    • Units: $M
    ini.requirements.ne_peaking

    On-axis electron density / volume-averaged electron denstiy

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.q_pol_omp

    Poloidal heat flux at the outer midplane

    • Type: Entry{Float64}
    • Units: W/m^2
    ini.requirements.lh_power_threshold_fraction

    Fraction of the LH power threshold

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.h98y2

    H98y2 ITER elmy H-mode confinement scaling factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.hds03

    Petty 2003 H-mode thermal energy confinement scaling factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.beta_normal

    Normalized total plasma beta (MHD)

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.Psol_R

    Psol / R

    • Type: Entry{Float64}
    • Units: W/m
    ini.requirements.q95

    Edge safety factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.coil_j_margin

    Magnet coil Jcrit / Jmax

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.4
    ini.requirements.coil_stress_margin

    Magnet coil yieldstress / maxstress

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.2
    +
    GitHub
    ini.general.casename

    Sort mnemonic name of the case being run

    • Type: Entry{String}
    • Units: -
    ini.general.description

    Longer description of the case being run

    • Type: Entry{String}
    • Units: -
    ini.general.init_from

    Initialize run from

    • Type: Switch{Symbol}
    • Units: -
    • Options: ods, scalars
    ini.general.dd

    dd to initialize from

    • Type: Entry{IMASdd.dd}
    • Units: -
    ini.time.pulse_shedule_time_basis

    Time basis used to discretize the pulse schedule

    • Type: Entry{AbstractRange{Float64}}
    • Units: s
    ini.time.simulation_start

    Time at which the simulation starts

    • Type: Entry{Float64}
    • Units: s
    • Default: 0.0
    ini.ods.filename

    ODS.json file(s) from which equilibrium is loaded. Multiple comma-separated ODSs can be specified.

    • Type: Entry{String}
    • Units: -
    ini.equilibrium.B0

    Vacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.

    • Type: Entry{Float64}
    • Units: T
    ini.equilibrium.R0

    Geometric genter of the plasma. NOTE: This also scales the radial build layers.

    • Type: Entry{Float64}
    • Units: m
    ini.equilibrium.Z0

    Z offset of the machine midplane

    • Type: Entry{Float64}
    • Units: m
    • Default: 0.0
    ini.equilibrium.ϵ

    Plasma inverse aspect ratio (a/R0). NOTE: This also scales the radial build layers.

    • Type: Entry{Float64}
    • Units: -
    ini.equilibrium.κ

    Plasma elongation. NOTE: If < 1.0 it defines the fraction of maximum controllable elongation estimate.

    • Type: Entry{Float64}
    • Units: -
    ini.equilibrium.tilt

    Tilt of the plasma boundary [MXH c0]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.δ

    Triangularity of the plasma boundary [MXH sin(s1)]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.ζ

    Squareness of the plasma boundary [MXH -s2]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.𝚶

    Ovality of the plasma boundary [MXH c1]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.twist

    Twist of the plasma boundary [MXH c2]

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.equilibrium.pressure_core

    On axis pressure

    • Type: Entry{Float64}
    • Units: Pa
    ini.equilibrium.ip

    Plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.

    • Type: Entry{Float64}
    • Units: A
    ini.equilibrium.xpoints

    X-points configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: lower, upper, double, none
    ini.equilibrium.ngrid

    Resolution of the equilibrium grid

    • Type: Entry{Int64}
    • Units: -
    • Default: 129
    ini.equilibrium.field_null_surface

    ψn value of the fieldnullsurface. Disable with 0.0

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.75
    ini.equilibrium.boundary_from

    The starting r, z boundary taken from

    • Type: Switch{Symbol}
    • Units: -
    • Options: scalars, MXH_params, rz_points, ods
    ini.equilibrium.MXH_params

    Vector of MXH flats

    • Type: Entry{Vector{Float64}}
    • Units: -
    ini.equilibrium.rz_points

    RZ boundary as Vector{Vector{Float64}}} : r = rzpoints[1], z = rz_points[2]

    • Type: Entry{Vector{Vector{Float64}}}
    • Units: m
    ini.core_profiles.plasma_mode

    Plasma configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: H_mode, L_mode
    • Default: H_mode
    ini.core_profiles.w_ped

    Pedestal width expressed in fraction of ψₙ

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.05
    ini.core_profiles.ne_value

    Value based on setup method

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.ne_setting

    Way to set the electron density

    • Type: Switch{Symbol}
    • Units: -
    • Options: ne_ped, ne_line, greenwald_fraction, greenwald_fraction_ped
    ini.core_profiles.ne_sep_to_ped_ratio

    Ratio used to set the sepeartrix density based on the pedestal density

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.25
    ini.core_profiles.ne_core_to_ped_ratio

    Ratio used to set the core density based on the pedestal density

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.4
    ini.core_profiles.ne_shaping

    Density shaping factor

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.T_ratio

    Ti/Te ratio

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.T_shaping

    Temperature shaping factor

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.Te_sep

    Separatrix temperature

    • Type: Entry{Float64}
    • Units: eV
    • Default: 80.0
    ini.core_profiles.zeff

    Effective ion charge

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.rot_core

    Derivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocity

    • Type: Entry{Float64}
    • Units: s^-1
    ini.core_profiles.ngrid

    Resolution of the core_profiles grid

    • Type: Entry{Int64}
    • Units: -
    • Default: 101
    ini.core_profiles.bulk

    Bulk ion species

    • Type: Entry{Symbol}
    • Units: -
    ini.core_profiles.impurity

    Impurity ion species

    • Type: Entry{Symbol}
    • Units: -
    ini.core_profiles.helium_fraction

    Helium density / electron density fraction

    • Type: Entry{Float64}
    • Units: -
    ini.core_profiles.ejima

    Ejima coefficient

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.4
    ini.core_profiles.polarized_fuel_fraction

    Spin polarized fuel fraction

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.pf_active.n_coils_inside

    Number of PF coils inside of the TF

    • Type: Entry{Int64}
    • Units: -
    ini.pf_active.n_coils_outside

    Number of PF coils outside of the TF

    • Type: Entry{Int64}
    • Units: -
    ini.pf_active.technology

    PF coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.rampup.side

    Side of the vacuum vessel where the plasma is limited at breakdown

    • Type: Switch{Symbol}
    • Units: -
    • Options: hfs, lfs
    ini.rampup.ends_at

    Until when does the rampup lasts

    • Type: Entry{Float64}
    • Units: s
    ini.rampup.diverted_at

    Time at which x-point is formed and plasma can peel-off the wall

    • Type: Entry{Float64}
    • Units: s
    ini.nb_unit.1.power_launched

    Beam power

    • Type: Entry{Float64}
    • Units: W
    ini.nb_unit.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.nb_unit.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.3
    ini.nb_unit.1.beam_energy

    Beam energy

    • Type: Entry{Float64}
    • Units: eV
    ini.nb_unit.1.beam_mass

    Beam mass

    • Type: Entry{Float64}
    • Units: AU
    • Default: 2.0
    ini.nb_unit.1.toroidal_angle

    Toroidal angle of injection

    • Type: Entry{Float64}
    • Units: rad
    ini.nb_unit.1.efficiency_conversion

    Conversion efficiency of electric power to neutral beam power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.nb_unit.1.efficiency_transmission

    Transmission efficiency of neutral beam from source to port

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ec_launcher.1.power_launched

    EC launched power

    • Type: Entry{Float64}
    • Units: W
    ini.ec_launcher.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.5
    ini.ec_launcher.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.025
    ini.ec_launcher.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ec_launcher.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.pellet_launcher.1.frequency

    Frequency of pellets launched

    • Type: Entry{Float64}
    • Units: Hz
    ini.pellet_launcher.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.5
    ini.pellet_launcher.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.25
    ini.pellet_launcher.1.shape

    The pellet geometry

    • Type: Switch{Symbol}
    • Units: -
    • Options: spherical, cylindrical, rectangular
    • Default: spherical
    ini.pellet_launcher.1.species

    Pellet species

    • Type: Switch{Symbol}
    • Units: -
    • Options: H, D, T, DT, C, Ne
    ini.pellet_launcher.1.size

    Vector of geometric dimensions describing the pellet size for a given shape (spherical: [r], cylindrical: [d, l], rectangular: [x,y,z])

    • Type: Entry{Vector{Float64}}
    • Units: m
    ini.ic_antenna.1.power_launched

    IC launched power

    • Type: Entry{Float64}
    • Units: W
    ini.ic_antenna.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.0
    ini.ic_antenna.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.1
    ini.ic_antenna.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ic_antenna.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.ic_antenna.1.efficiency_coupling

    Coupling efficiency of launched microwave power to the plasma

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.power_launched

    LH launched power

    • Type: Entry{Float64}
    • Units: W
    ini.lh_antenna.1.rho_0

    Desired radial location of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.8
    ini.lh_antenna.1.width

    Desired width of the deposition profile

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.05
    ini.lh_antenna.1.efficiency_conversion

    Conversion efficiency of electric power to microwave power

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.efficiency_transmission

    Transmission efficiency of microwave power from generator to antenna

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.lh_antenna.1.efficiency_coupling

    Coupling efficiency of launched microwave power to the plasma

    • Type: Entry{Float64}
    • Units: -
    • Default: 1.0
    ini.hcd.power_scaling_cost_function

    EC, IC, LH, NB power optimization cost function, takes dd as input. Eg. dd -> (1.0 - IMAS.tauethermal(dd) / IMAS.taueh98(dd))

    • Type: Entry{Function}
    • Units: -
    ini.build.layers.1.name

    Name of the layer

    • Type: Entry{String}
    • Units: -
    ini.build.layers.1.thickness

    Relative thickness of the layer (layers actual thickness is scaled to match plasma R0)

    • Type: Entry{Float64}
    • Units: -
    ini.build.layers.1.material

    Material of the layer

    • Type: Switch{Symbol}
    • Units: -
    • Options: tungsten, aluminum, graphite, nbti, flibe, water, plasma, lithium_lead, nb3sn_iter, nb3sn, vacuum, rebco, steel, nb3sn_kdemo, copper
    ini.build.layers.1.shape

    Shape of the layer

    • Type: Switch{IMAS.BuildLayerShape}
    • Units: -
    • Options: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc
    ini.build.layers.1.type

    Type of the layer

    • Type: Switch{IMAS.BuildLayerType}
    • Units: -
    • Options: blanket, cryostat, gap, vessel, tf, oh, shield, port, wall, plasma, divertor
    ini.build.layers.1.side

    Side of the layer

    • Type: Switch{IMAS.BuildLayerSide}
    • Units: -
    • Options: hfs, in, lfs, out, lhfs
    ini.build.plasma_gap

    Fraction of vacuum gap between first wall and plasma separatrix in radial build

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.1
    ini.build.symmetric

    Is the build up-down symmetric

    • Type: Entry{Bool}
    • Units: -
    ini.build.divertors

    Divertors configuration

    • Type: Switch{Symbol}
    • Units: -
    • Options: lower, upper, double, none, from_x_points
    • Default: from_x_points
    ini.build.n_first_wall_conformal_layers

    Number of layers that are conformal to the first wall

    • Type: Entry{Int64}
    • Units: -
    • Default: 1
    ini.center_stack.bucked

    Flag for bucked boundary conditions between TF and OH (and center plug, if present)

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.center_stack.noslip

    Flag for no slip conditions between TF and OH (and center plug, if present)

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.center_stack.plug

    Flag for center plug

    • Type: Entry{Bool}
    • Units: -
    • Default: false
    ini.tf.n_coils

    Number of TF coils

    • Type: Entry{Int64}
    • Units: -
    ini.tf.shape

    Shape of the TF coils

    • Type: Switch{IMAS.BuildLayerShape}
    • Units: -
    • Options: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc
    ini.tf.ripple

    Fraction of toroidal field ripple evaluated at the outermost radius of the plasma chamber

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.01
    ini.tf.technology

    TF coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.oh.n_coils

    Number of OH coils

    • Type: Entry{Int64}
    • Units: -
    ini.oh.technology

    OH coils technology

    • Type: Switch{Symbol}
    • Units: -
    • Options: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper
    ini.bop.cycle_type

    Thermal cycle type

    • Type: Switch{Symbol}
    • Units: -
    • Options: rankine, brayton
    • Default: rankine
    ini.requirements.power_electric_net

    Net electric power generated by the fusion power plant

    • Type: Entry{Float64}
    • Units: W
    ini.requirements.flattop_duration

    Duration of the flattop (use Inf for steady-state)

    • Type: Entry{Float64}
    • Units: s
    ini.requirements.log10_flattop_duration

    Log10 value of the duration of the flattop (use Inf for steady-state). Preferred over flattop_duration for optimization studies.

    • Type: Entry{Float64}
    • Units: log10(s)
    ini.requirements.tritium_breeding_ratio

    Tritium breeding ratio of the whole plant

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.cost

    Total FPP cost

    • Type: Entry{Float64}
    • Units: $M
    ini.requirements.ne_peaking

    On-axis electron density / volume-averaged electron denstiy

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.q_pol_omp

    Poloidal heat flux at the outer midplane

    • Type: Entry{Float64}
    • Units: W/m^2
    ini.requirements.lh_power_threshold_fraction

    Fraction of the LH power threshold

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.h98y2

    H98y2 ITER elmy H-mode confinement scaling factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.hds03

    Petty 2003 H-mode thermal energy confinement scaling factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.beta_normal

    Normalized total plasma beta (MHD)

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.Psol_R

    Psol / R

    • Type: Entry{Float64}
    • Units: W/m
    ini.requirements.q95

    Edge safety factor

    • Type: Entry{Float64}
    • Units: -
    ini.requirements.coil_j_margin

    Magnet coil Jcrit / Jmax

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.4
    ini.requirements.coil_stress_margin

    Magnet coil yieldstress / maxstress

    • Type: Entry{Float64}
    • Units: -
    • Default: 0.2
    diff --git a/dev/inits.html b/dev/inits.html index 2faed10e1..4802178ef 100644 --- a/dev/inits.html +++ b/dev/inits.html @@ -11,4 +11,4 @@ initialize_hardware::Bool=true, initialize_pulse_schedule::Bool=true, restore_expressions::Bool=true, - verbose::Bool=false)

    Initialize dd starting from ini and act parameters

    FUSE provides this high-level init function to populate dd starting from the ini parameters.

    This function essentially calls all other FUSE.init... functions in FUSE.

    For most studies, calling this high level function is sufficient.

    source

    Use-cases initialization

    FUSE.initMethod
    init(case::Symbol; do_plot::Bool=false, kw...)

    Initialize dd, ini, act based on a given use-case.

    Returns a tuple with dd, ini, act.

    source

    Low-level initialization routines

    Below are the initialization functions specific to IDSs in the dd data structure. These can be called for a fine control on what IDSs are initialized and how.

    balance of plant!

    FUSE.init_balance_of_plant!Method
    init_balance_of_plant!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.balance_of_plant starting from ini and act parameters

    source

    build!

    FUSE.init_build!Method
    init_build!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.build starting from ini and act parameters

    source

    core profiles!

    FUSE.init_core_profiles!Method
    init_core_profiles!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.core_profiles starting from ini and act parameters

    source

    core sources!

    FUSE.init_core_sources!Method
    init_core_sources!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.nbi, dd.ec_launchers, dd.ic_antennas, dd.lh_antennas starting from ini and act parameters

    source

    currents!

    FUSE.init_currents!Method
    init_currents!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.core_profiles and dd.core_sources ohmic and bootstrap currents and sources starting from ini and act parameters

    source

    ec

    FUSE.init_ecMethod
    init_ec(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.ec_launchers starting from ini and act parameters

    source

    equilibrium!

    FUSE.init_equilibrium!Method
    init_equilibrium!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.equilibrium starting from ini and act parameters

    source

    expressions

    Missing docstring.

    Missing docstring for FUSE.init_expressions(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors). Check Documenter's build log for details.

    ic

    FUSE.init_icMethod
    init_ic(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.ic_antennas starting from ini and act parameters

    source

    lh

    FUSE.init_lhMethod
    init_lh(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.lh_antennas starting from ini and act parameters

    source

    missing from ods!

    FUSE.init_missing_from_ods!Method
    init_missing_from_ods!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize missing IDSs from ODS, only if ini.general.init_from == :ods.

    source

    nb

    FUSE.init_nbMethod
    init_nb(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.nbi starting from ini and act parameters

    source

    pf active!

    FUSE.init_pf_active!Method
    init_pf_active!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.pf_active starting from ini and act parameters

    source

    pl

    FUSE.init_plMethod
    init_pl(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.pellet_launcher starting from ini and act parameters

    source

    pulse schedule!

    FUSE.init_pulse_schedule!Method
    init_pulse_schedule!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd(); simplify_time_traces::Float64=0.1)

    Initialize dd.pulse_schedule starting from ini and act parameters

    source

    pulse schedule postion control

    Missing docstring.

    Missing docstring for FUSE.init_pulse_schedule_postion_control(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors). Check Documenter's build log for details.

    requirements!

    FUSE.init_requirements!Method
    init_requirements!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.requirements ini.requirements

    source
    + verbose::Bool=false)

    Initialize dd starting from ini and act parameters

    FUSE provides this high-level init function to populate dd starting from the ini parameters.

    This function essentially calls all other FUSE.init... functions in FUSE.

    For most studies, calling this high level function is sufficient.

    source

    Use-cases initialization

    FUSE.initMethod
    init(case::Symbol; do_plot::Bool=false, kw...)

    Initialize dd, ini, act based on a given use-case.

    Returns a tuple with dd, ini, act.

    source

    Low-level initialization routines

    Below are the initialization functions specific to IDSs in the dd data structure. These can be called for a fine control on what IDSs are initialized and how.

    balance of plant!

    FUSE.init_balance_of_plant!Method
    init_balance_of_plant!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.balance_of_plant starting from ini and act parameters

    source

    build!

    FUSE.init_build!Method
    init_build!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.build starting from ini and act parameters

    source

    core profiles!

    FUSE.init_core_profiles!Method
    init_core_profiles!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.core_profiles starting from ini and act parameters

    source

    core sources!

    FUSE.init_core_sources!Method
    init_core_sources!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.nbi, dd.ec_launchers, dd.ic_antennas, dd.lh_antennas starting from ini and act parameters

    source

    currents!

    FUSE.init_currents!Method
    init_currents!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.core_profiles and dd.core_sources ohmic and bootstrap currents and sources starting from ini and act parameters

    source

    ec

    FUSE.init_ecMethod
    init_ec(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.ec_launchers starting from ini and act parameters

    source

    equilibrium!

    FUSE.init_equilibrium!Method
    init_equilibrium!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.equilibrium starting from ini and act parameters

    source

    expressions

    Missing docstring.

    Missing docstring for FUSE.init_expressions(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors). Check Documenter's build log for details.

    ic

    FUSE.init_icMethod
    init_ic(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.ic_antennas starting from ini and act parameters

    source

    lh

    FUSE.init_lhMethod
    init_lh(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.lh_antennas starting from ini and act parameters

    source

    missing from ods!

    FUSE.init_missing_from_ods!Method
    init_missing_from_ods!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize missing IDSs from ODS, only if ini.general.init_from == :ods.

    source

    nb

    FUSE.init_nbMethod
    init_nb(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.nbi starting from ini and act parameters

    source

    pf active!

    FUSE.init_pf_active!Method
    init_pf_active!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.pf_active starting from ini and act parameters

    source

    pl

    FUSE.init_plMethod
    init_pl(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.pellet_launcher starting from ini and act parameters

    source

    pulse schedule!

    FUSE.init_pulse_schedule!Method
    init_pulse_schedule!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd(); simplify_time_traces::Float64=0.1)

    Initialize dd.pulse_schedule starting from ini and act parameters

    source

    pulse schedule postion control

    Missing docstring.

    Missing docstring for FUSE.init_pulse_schedule_postion_control(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors). Check Documenter's build log for details.

    requirements!

    FUSE.init_requirements!Method
    init_requirements!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())

    Initialize dd.requirements ini.requirements

    source
    diff --git a/dev/install.html b/dev/install.html index 535ca17c9..cd5a22d97 100644 --- a/dev/install.html +++ b/dev/install.html @@ -6,4 +6,4 @@
    GitHub

    Setup the FUSE environment

    Julia installation

    We highly recommend using the Juliaup manager to install Julia

    • Mac & Linux: curl -fsSL https://install.julialang.org | sh
    • Windows: winget install julia -s msstore

    Once installed, restart your termninal to pick-up the julia executable.

    FUSE installation

    FUSE and related packages are registered at the FuseRegistry. For installation start your Julia interpreter by typing julia at the terminal, then:

    1. Add the FuseRegistry and the FUSE package as you would for any other julia package (for a fresh install this can take 20+ mins):

      using Pkg
 Pkg.Registry.add(RegistrySpec(url="https://github.com/ProjectTorreyPines/FuseRegistry.jl.git"))
 Pkg.Registry.add("General")
-Pkg.add("FUSE")

    2. Now you should be able to import the FUSE package:

      using FUSE

    3. Install the fusebot utility to simplify install/updates later on. Now fusebot should be a command that you can type anywhere from the terminal.

      FUSE.install_fusebot()

    4. Run the regression tests (optional, this can take 1h+)

      julia ] test FUSE

    5. Exit julia and clone FUSE examples in the current working directory. To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.

      fusebot install_examples

    Keeping FUSE up-to-date

    1. Get notified of new FUSE releases by "watching" the FUSE repo on GitHub

    2. FUSE is updated like any other Julia package:

      julia ] up

    Tip

    Become familiar with how managing Julia packages works.

    Install Jupyter-Lab and add the Julia kernel to it

    1. You will need to install jupyter-lab if that's not already available on your system

    2. Install the IJulia package by running:

      fusebot install_IJulia
      Note

      Run fusebot install_IJulia every time a new julia version is installed.

      This will setup the single- and multi-thread julia kernels in Jupyter.

      The number of threads of the multi-threaded julia kernels can be set via the JULIA_NUM_THREADS environmental variable.

    3. Start a new Jupyter-lab session (this should open a web-browser page with Jupyter running)

      jupyter-lab

    4. Now you can browse the examples in the FuseExamples folder that you have cloned, and take a tour of the example Jupyter notebooks there.

    +Pkg.add("FUSE")

  • Now you should be able to import the FUSE package:

    using FUSE

  • Install the fusebot utility to simplify install/updates later on. Now fusebot should be a command that you can type anywhere from the terminal.

    FUSE.install_fusebot()

  • Run the regression tests (optional, this can take 1h+)

    julia ] test FUSE

  • Exit julia and clone FUSE examples in the current working directory. To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.

    fusebot install_examples

    • Keeping FUSE up-to-date

    1. Get notified of new FUSE releases by "watching" the FUSE repo on GitHub

    2. FUSE is updated like any other Julia package:

      julia ] up

    Tip

    Become familiar with how managing Julia packages works.

    Install Jupyter-Lab and add the Julia kernel to it

    1. You will need to install jupyter-lab if that's not already available on your system

    2. Install the IJulia package by running:

      fusebot install_IJulia
      Note

      Run fusebot install_IJulia every time a new julia version is installed.

      This will setup the single- and multi-thread julia kernels in Jupyter.

      The number of threads of the multi-threaded julia kernels can be set via the JULIA_NUM_THREADS environmental variable.

    3. Start a new Jupyter-lab session (this should open a web-browser page with Jupyter running)

      jupyter-lab

    4. Now you can browse the examples in the FuseExamples folder that you have cloned, and take a tour of the example Jupyter notebooks there.

    diff --git a/dev/install_omega.html b/dev/install_omega.html index 234d9fb21..a022f78fd 100644 --- a/dev/install_omega.html +++ b/dev/install_omega.html @@ -28,4 +28,4 @@ ProxyCommand ssh -q cybele nc %h %p

  • On your computer start a tunnel going through cybele to omega

    ssh -N -L localhost:33445:localhost:55667 omegae
    Note

    Keep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.

  • On your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on omega. Use the token when prompted.

    • Using Revise on OMEGA

    When working on omega it seems ones need to manually trigger revise to pick up code changes:

    import Revise
 Revise.revise()  # manual trigger

    This is even if setting JULIA_REVISE_POLL=1

    Using GACODE on OMEGA with Julia

    Julia may be incompatible with some environments and will crash when launched. This is the case for the GACODE environment on OMEGA. To be able to run both GACODE and Julia on OMEGA (eg. to run NEO and TGLF) do the following:

    module load atom
 module unload gcc
-module unload env
    +module unload env diff --git a/dev/install_saga.html b/dev/install_saga.html index 0473aa08a..00c65924e 100644 --- a/dev/install_saga.html +++ b/dev/install_saga.html @@ -14,4 +14,4 @@ Host sagae saga.gat.com Hostname saga.gat.com User meneghini -ProxyCommand ssh -q cybele nc %h %p

  • On your computer start a tunnel going through cybele to saga

    ssh -N -L localhost:33445:localhost:55667 sagae
    Note

    Keep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.

  • On your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on saga. Use the token when prompted.

    • +ProxyCommand ssh -q cybele nc %h %p

  • On your computer start a tunnel going through cybele to saga

    ssh -N -L localhost:33445:localhost:55667 sagae
    Note

    Keep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.

  • On your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on saga. Use the token when prompted.

    • diff --git a/dev/license.html b/dev/license.html index acff39805..2b0824906 100644 --- a/dev/license.html +++ b/dev/license.html @@ -12,4 +12,4 @@ comment syntax for the file format. We also recommend that a file or class name and description of purpose be included on the same "printed page" as the copyright notice for easier - identification within third-party archives.

    Copyright 2024 General Atomics

    Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at

       http://www.apache.org/licenses/LICENSE-2.0

    Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

    + identification within third-party archives.

    Copyright 2024 General Atomics

    Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at

       http://www.apache.org/licenses/LICENSE-2.0

    Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

    diff --git a/dev/notice.html b/dev/notice.html index 11ef147c0..8b8e9b1f1 100644 --- a/dev/notice.html +++ b/dev/notice.html @@ -9,4 +9,4 @@ journal = {arXiv}, title = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}}, year = {2024} -}

    Trademark Notice

    The names "General Atomics", and any associated logos or images, are trademarks of General Atomics. Use of these trademarks without prior written consent from General Atomics is strictly prohibited. Users cannot imply endorsement by General Atomics or contributors to the project simply because the project is part of their work.

    Copyright (c) 2024 General Atomics

    Version

    Version: v2.1

    +}

    Trademark Notice

    The names "General Atomics", and any associated logos or images, are trademarks of General Atomics. Use of these trademarks without prior written consent from General Atomics is strictly prohibited. Users cannot imply endorsement by General Atomics or contributors to the project simply because the project is part of their work.

    Copyright (c) 2024 General Atomics

    Version

    Version: v2.1

    diff --git a/dev/pubs.html b/dev/pubs.html index 9970e6734..3ee38b99c 100644 --- a/dev/pubs.html +++ b/dev/pubs.html @@ -3,4 +3,4 @@ function gtag(){dataLayer.push(arguments);} gtag('js', new Date()); gtag('config', 'G-65D8V8C8VQ', {'page_path': location.pathname + location.search + location.hash}); -
    GitHub

    Publications

    Taks/Posters

    APS DPP 2024

    IMEG 2024

    Juliacon 2024

    Sherwood 2024

    IMEG 2023

    +
    GitHub

    Publications

    Taks/Posters

    APS DPP 2024

    IMEG 2024

    Juliacon 2024

    Sherwood 2024

    IMEG 2023

    diff --git a/dev/search_index.js b/dev/search_index.js index 6e3899267..84c5d3946 100644 --- a/dev/search_index.js +++ b/dev/search_index.js @@ -1,3 +1,3 @@ var documenterSearchIndex = {"docs": -[{"location":"cases.html#Use-cases","page":"Use Cases","title":"Use cases","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"CurrentModule = FUSE","category":"page"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"FUSE comes with a set of pre-cookes used cases. The case_parameters(:use_case, ...) method returns the ini and act parameters for that specific use_case. These ini and act can then be further customized before running a FUSE simulation.","category":"page"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"To create your own case and add them to FUSE/cases copy one of the other cases as a template and change the ini/act parameters inside. 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kw...)","category":"page"},{"location":"actors.html#FUSE.ActorBalanceOfPlant-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorBalanceOfPlant","text":"ActorBalanceOfPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nBalance of plant actor that estimates the net electrical power output by comparing the balance of plant electrical needs with the electricity generated from the thermal cycle.\n\nnote: Note\n\n\nStores data in dd.balance_of_plant\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorBalanceOfPlant) # hide","category":"page"},{"location":"actors.html#PowerNeeds","page":"List of actors","title":"PowerNeeds","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPowerNeeds(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPowerNeeds-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPowerNeeds","text":"ActorPowerNeeds(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nPower needs actor that calculates the needed power to operate the plant\n\nmodel = :thermal_power_fraction simply assumes that the power to balance a plant is a fraction of the gross electrical power generated by the thermal cycle.\nmodel = :EU_DEMO subdivides the power plant electrical needs to [:cryostat, :tritium_handling, :pumping] using EU-DEMO numbers.\nmodel = :FUSE subdivides power plant needs into subsystems and calculates their power needs.\n\nnote: Note\n\n\nStores data in dd.balance_of_plant.power_electric_plant_operation\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPowerNeeds) # hide","category":"page"},{"location":"actors.html#ThermalPlant","page":"List of actors","title":"ThermalPlant","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorThermalPlant(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorThermalPlant-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorThermalPlant","text":"ActorThermalPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nnote: Note\nStores data in dd.balance_of_plant\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorThermalPlant) # hide","category":"page"},{"location":"actors.html#Build-(5-actors)","page":"List of actors","title":"Build (5 actors)","text":"","category":"section"},{"location":"actors.html#CXbuild","page":"List of actors","title":"CXbuild","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCXbuild(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCXbuild-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCXbuild","text":"ActorCXbuild(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nGenerates the 2D cross section of the tokamak build\n\nnote: Note\nManipulates data in dd.build\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCXbuild) # hide","category":"page"},{"location":"actors.html#HFSsizing","page":"List of actors","title":"HFSsizing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorHFSsizing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorHFSsizing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorHFSsizing","text":"ActorHFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nActor that resizes the High Field Side of the tokamak radial build\n\ntakes into account the OH maximum allowed superconductor current/Field\ntakes into account the stresses on the center stack\n\nnote: Note\nManipulates radial build information in dd.build.layer\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorHFSsizing) # hide","category":"page"},{"location":"actors.html#FluxSwing","page":"List of actors","title":"FluxSwing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxSwing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxSwing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxSwing","text":"ActorFluxSwing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nDepending on operate_oh_at_j_crit\n\ntrue => Evaluate the OH current limits, and evaluate flattop duration from that.\nfalse => Evaluate what are the currents needed for a given flattop duration. This may or may not exceed the OH current limits.\n\nOH flux consumption based on:\n\nrampup estimate based on Ejima coefficient\nflattop consumption\nvertical field from PF coils\n\nnote: Note\nStores data in dd.build.flux_swing, dd.build.tf, and dd.build.oh\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxSwing) # hide","category":"page"},{"location":"actors.html#LFSsizing","page":"List of actors","title":"LFSsizing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorLFSsizing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorLFSsizing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorLFSsizing","text":"ActorLFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nActor that resizes the Low Field Side of the tokamak radial build\n\nPlaces TF outer leg at radius required to meet the dd.build.tf.ripple requirement\nOther low-field side layers are scaled proportionally\n\nnote: Note\n\n\nManipulates radial build information in dd.build.layer\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorLFSsizing) # hide","category":"page"},{"location":"actors.html#Stresses","page":"List of actors","title":"Stresses","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStresses(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStresses-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStresses","text":"ActorStresses(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates mechanical stresses on the center stack\n\nnote: Note\nStores data in dd.solid_mechanics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStresses) # hide","category":"page"},{"location":"actors.html#Compound-(3-actors)","page":"List of actors","title":"Compound (3 actors)","text":"","category":"section"},{"location":"actors.html#DynamicPlasma","page":"List of actors","title":"DynamicPlasma","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorDynamicPlasma(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorDynamicPlasma-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorDynamicPlasma","text":"ActorDynamicPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound evolves plasma in time\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorDynamicPlasma) # hide","category":"page"},{"location":"actors.html#StationaryPlasma","page":"List of actors","title":"StationaryPlasma","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStationaryPlasma(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStationaryPlasma-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStationaryPlasma","text":"ActorStationaryPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound actor that runs the following actors in succesion:\n\nActorCurrent\nActorHCD\nActorCoreTransport\nActorEquilibrium\n\nnote: Note\nStores data in dd.equilibrium, dd.core_profiles, dd.core_sources, dd.core_transport\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStationaryPlasma) # hide","category":"page"},{"location":"actors.html#WholeFacility","page":"List of actors","title":"WholeFacility","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorWholeFacility(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorWholeFacility-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorWholeFacility","text":"ActorWholeFacility(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound actor that runs all the physics, engineering and costing actors needed to model the whole plant:\n\nActorStationaryPlasma\nActorStabilityLimits\nActorHFSsizing\nActorLFSsizing\nActorCXbuild\nActorFluxSwing\nActorStresses\nActorPFdesign\nActorPFactive\nActorPassiveStructures\nActorVerticalStability\nActorNeutronics\nActorBlanket\nActorDivertors\nActorBalanceOfPlant\nActorCosting\n\nnote: Note\nStores data in dd\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorWholeFacility) # hide","category":"page"},{"location":"actors.html#Costing-(3-actors)","page":"List of actors","title":"Costing (3 actors)","text":"","category":"section"},{"location":"actors.html#Costing","page":"List of actors","title":"Costing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCosting(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCosting-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCosting","text":"ActorCosting(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the cost of building, operating, and recommission the fusion power plant.\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCosting) # hide","category":"page"},{"location":"actors.html#CostingARIES","page":"List of actors","title":"CostingARIES","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCostingARIES(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCostingARIES-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCostingARIES","text":"ActorCostingARIES(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates costing based on ARIES cost account documentation https://cer.ucsd.edu/_files/publications/UCSD-CER-13-01.pdf\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCostingARIES) # hide","category":"page"},{"location":"actors.html#CostingSheffield","page":"List of actors","title":"CostingSheffield","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCostingSheffield(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCostingSheffield-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCostingSheffield","text":"ActorCostingSheffield(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates costing based on Sheffield and Milora, FS&T 70 (2016)\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCostingSheffield) # hide","category":"page"},{"location":"actors.html#Current-(3-actors)","page":"List of actors","title":"Current (3 actors)","text":"","category":"section"},{"location":"actors.html#Current","page":"List of actors","title":"Current","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCurrent(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCurrent-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCurrent","text":"ActorCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple ohmic current evolution actors\n\nSets the j_ohmic, j_tor, j_total under dd.core_profiles.profiles_1d[]\nSets j_parallel in dd.equilibrium.time_slice[].profiles_1d\nUpdates bootstrap and ohmic parallel current and heating sources in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCurrent) # hide","category":"page"},{"location":"actors.html#QED","page":"List of actors","title":"QED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorQED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorQED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorQED","text":"ActorQED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvolves the plasma current using the QED current diffusion solver.\n\nnote: Note\nThis actor operates at \"dd.global_time\", any time advance must be done outside of the actorIMAS.new_timeslice!(dd, dd.global_time + Δt)\ndd.global_time += Δt\nActorQED(dd, act)\n\nnote: Note\nStores data in dd.core_profiles.profiles_1d[].j_ohmic\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorQED) # hide","category":"page"},{"location":"actors.html#SteadyStateCurrent","page":"List of actors","title":"SteadyStateCurrent","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSteadyStateCurrent(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSteadyStateCurrent-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSteadyStateCurrent","text":"ActorSteadyStateCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvolves the ohmic current to steady state using the conductivity from dd.core_profiles\n\nnote: Note\nStores data in dd.core_profiles.profiles_1d[].j_ohmic\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSteadyStateCurrent) # hide","category":"page"},{"location":"actors.html#Divertors-(1-actors)","page":"List of actors","title":"Divertors (1 actors)","text":"","category":"section"},{"location":"actors.html#Divertors","page":"List of actors","title":"Divertors","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorDivertors(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorDivertors-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorDivertors","text":"ActorDivertors(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates divertor loading and deposited power\n\nnote: Note\nStores data in dd.divertors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorDivertors) # hide","category":"page"},{"location":"actors.html#Equilibrium-(4-actors)","page":"List of actors","title":"Equilibrium (4 actors)","text":"","category":"section"},{"location":"actors.html#Equilibrium","page":"List of actors","title":"Equilibrium","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEquilibrium(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEquilibrium-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEquilibrium","text":"ActorEquilibrium(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple equilibrium actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEquilibrium) # hide","category":"page"},{"location":"actors.html#CHEASE","page":"List of actors","title":"CHEASE","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCHEASE(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCHEASE-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCHEASE","text":"ActorCHEASE(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns the Fixed boundary equilibrium solver CHEASE\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCHEASE) # hide","category":"page"},{"location":"actors.html#Solovev","page":"List of actors","title":"Solovev","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSolovev(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSolovev-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSolovev","text":"ActorSolovev(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nSolovev equilibrium actor, based on: “One size fits all” analytic solutions to the Grad–Shafranov equation Phys. Plasmas 17, 032502 (2010); https://doi.org/10.1063/1.3328818\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSolovev) # hide","category":"page"},{"location":"actors.html#TEQUILA","page":"List of actors","title":"TEQUILA","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorTEQUILA(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorTEQUILA-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorTEQUILA","text":"ActorTEQUILA(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns the Fixed boundary equilibrium solver TEQUILA\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorTEQUILA) # hide","category":"page"},{"location":"actors.html#Hcd-(5-actors)","page":"List of actors","title":"Hcd (5 actors)","text":"","category":"section"},{"location":"actors.html#HCD","page":"List of actors","title":"HCD","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorHCD(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorHCD-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorHCD","text":"ActorHCD(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run HCD actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorHCD) # hide","category":"page"},{"location":"actors.html#SimpleEC","page":"List of actors","title":"SimpleEC","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleEC(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleEC-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleEC","text":"ActorSimpleEC(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the EC electron energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.ec_launchers, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleEC) # hide","category":"page"},{"location":"actors.html#SimpleIC","page":"List of actors","title":"SimpleIC","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleIC(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleIC-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleIC","text":"ActorSimpleIC(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the ion-cyclotron electron/ion energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.ic_antennas, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleIC) # hide","category":"page"},{"location":"actors.html#SimpleLH","page":"List of actors","title":"SimpleLH","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleLH(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleLH-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleLH","text":"ActorSimpleLH(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the Lower-hybrid electron energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.lh_antennas, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleLH) # hide","category":"page"},{"location":"actors.html#SimplePellet","page":"List of actors","title":"SimplePellet","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimplePellet(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimplePellet-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimplePellet","text":"ActorSimplePellet(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the Pellet particle deposition\n\nnote: Note\nReads data in dd.pellet_launchers, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimplePellet) # hide","category":"page"},{"location":"actors.html#Nuclear-(2-actors)","page":"List of actors","title":"Nuclear (2 actors)","text":"","category":"section"},{"location":"actors.html#Blanket","page":"List of actors","title":"Blanket","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorBlanket(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorBlanket-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorBlanket","text":"ActorBlanket(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates blankets tritium breeding ratio (TBR), heat deposition, and neutron leakage\n\nnote: Note\nStores data in dd.blanket\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorBlanket) # hide","category":"page"},{"location":"actors.html#Neutronics","page":"List of actors","title":"Neutronics","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorNeutronics(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorNeutronics-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorNeutronics","text":"ActorNeutronics(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the neutron wall loading\n\nnote: Note\nStores data in dd.neutronics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorNeutronics) # hide","category":"page"},{"location":"actors.html#Pedestal-(3-actors)","page":"List of actors","title":"Pedestal (3 actors)","text":"","category":"section"},{"location":"actors.html#Pedestal","page":"List of actors","title":"Pedestal","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPedestal(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPedestal-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPedestal","text":"ActorPedestal(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the pedestal boundary condition (height and width)\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPedestal) # hide","category":"page"},{"location":"actors.html#EPED","page":"List of actors","title":"EPED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEPED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEPED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEPED","text":"ActorEPED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the pedestal boundary condition (height and width)\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEPED) # hide","category":"page"},{"location":"actors.html#WPED","page":"List of actors","title":"WPED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorWPED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorWPED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorWPED","text":"ActorWPED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nFinds the temperature profile at the edge to match the pedtocorefraction of stored energy set in par.pedtocorefraction\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorWPED) # hide","category":"page"},{"location":"actors.html#Pf-(3-actors)","page":"List of actors","title":"Pf (3 actors)","text":"","category":"section"},{"location":"actors.html#PFdesign","page":"List of actors","title":"PFdesign","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPFdesign(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPFdesign-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPFdesign","text":"ActorPFdesign(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nOptimize PF coil locations to achieve desired equilibrium\n\nnote: Note\nManupulates data in dd.pf_active\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPFdesign) # hide","category":"page"},{"location":"actors.html#PFactive","page":"List of actors","title":"PFactive","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPFactive(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPFactive-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPFactive","text":"ActorPFactive(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nFinds the optimal coil currents to match the equilibrium boundary shape\n\nnote: Note\nManupulates data in dd.pf_active\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPFactive) # hide","category":"page"},{"location":"actors.html#PassiveStructures","page":"List of actors","title":"PassiveStructures","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPassiveStructures(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPassiveStructures-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPassiveStructures","text":"ActorPassiveStructures(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nPopulates pf_passive structures\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPassiveStructures) # hide","category":"page"},{"location":"actors.html#Stability-(2-actors)","page":"List of actors","title":"Stability (2 actors)","text":"","category":"section"},{"location":"actors.html#StabilityLimits","page":"List of actors","title":"StabilityLimits","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStabilityLimits(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStabilityLimits-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStabilityLimits","text":"ActorStabilityLimits(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns all the limit actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStabilityLimits) # hide","category":"page"},{"location":"actors.html#VerticalStability","page":"List of actors","title":"VerticalStability","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorVerticalStability(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorVerticalStability-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorVerticalStability","text":"ActorVerticalStability(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompute vertical stability metrics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorVerticalStability) # hide","category":"page"},{"location":"actors.html#Transport-(7-actors)","page":"List of actors","title":"Transport (7 actors)","text":"","category":"section"},{"location":"actors.html#CoreTransport","page":"List of actors","title":"CoreTransport","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCoreTransport(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCoreTransport-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCoreTransport","text":"ActorCoreTransport(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple core transport actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCoreTransport) # hide","category":"page"},{"location":"actors.html#EPEDprofiles","page":"List of actors","title":"EPEDprofiles","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEPEDprofiles(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEPEDprofiles-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEPEDprofiles","text":"ActorEPEDprofiles(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nUpdates pedestal height and width and blends with core profiles that are defined by shaping factors.\n\nDoes not change on-axis values of plasma profiles.\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEPEDprofiles) # hide","category":"page"},{"location":"actors.html#FluxCalculator","page":"List of actors","title":"FluxCalculator","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxCalculator(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxCalculator-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxCalculator","text":"ActorFluxCalculator(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple transport model actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxCalculator) # hide","category":"page"},{"location":"actors.html#FluxMatcher","page":"List of actors","title":"FluxMatcher","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxMatcher(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxMatcher-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxMatcher","text":"ActorFluxMatcher(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvalutes the transport fluxes and source fluxes and minimizes the flux_match error\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxMatcher) # hide","category":"page"},{"location":"actors.html#Neoclassical","page":"List of actors","title":"Neoclassical","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorNeoclassical(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorNeoclassical-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorNeoclassical","text":"ActorNeoclassical(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the neoclassical transport fluxes\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorNeoclassical) # hide","category":"page"},{"location":"actors.html#QLGYRO","page":"List of actors","title":"QLGYRO","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorQLGYRO(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorQLGYRO-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorQLGYRO","text":"ActorQLGYRO(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the QLGYRO predicted turbulence\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorQLGYRO) # hide","category":"page"},{"location":"actors.html#TGLF","page":"List of actors","title":"TGLF","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorTGLF(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorTGLF-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorTGLF","text":"ActorTGLF(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the TGLF predicted turbulence\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorTGLF) # hide","category":"page"},{"location":"actors.html#Wall-loading-(2-actors)","page":"List of actors","title":"Wall loading (2 actors)","text":"","category":"section"},{"location":"actors.html#CoreRadHeatFlux","page":"List of actors","title":"CoreRadHeatFlux","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCoreRadHeatFlux(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCoreRadHeatFlux-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCoreRadHeatFlux","text":"ActorCoreRadHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nComputes the heat flux on the wall due to the core radiation\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCoreRadHeatFlux) # hide","category":"page"},{"location":"actors.html#ParticleHeatFlux","page":"List of actors","title":"ParticleHeatFlux","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorParticleHeatFlux(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorParticleHeatFlux-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorParticleHeatFlux","text":"ActorParticleHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nComputes the heat flux on the wall due to the charged particles\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorParticleHeatFlux) # hide","category":"page"},{"location":"develop.html#Contributing","page":"Contributing","title":"Contributing","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"FUSE is a collaborative project that welcomes community contributions!","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The master branch of ProjectTorreyPines repositories is write-protected. This means that even with write permissions to the repository, you'll not be able to push to master directly. Instead, we handle updates – be it new features or bug fixes – through branches and Pull Requests (PRs).","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"A crucial part of our PR process is code review. It is where your peers get to weigh in and ensure everything is up to standard before merging. When you create a PR, think about who on the team has the right expertise for the code you're working on, and assign them as reviewers. Their insights will not only help in maintaining code quality but also in catching any potential issues early. It is all about teamwork and making sure our code is the best it can be!","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nWhen working on a new feature that involves changes to FUSE and other ProjectTorreyPines repositories, you'll want to use the same branch name across these repositories. For example, if you're working on a branch named my_new_feature in both FUSE and IMAS, regression testing will be performed using the my_new_feature branches for FUSE and IMAS, along with the master branch of the other ProjectTorreyPines repositories.","category":"page"},{"location":"develop.html#Add/modify-entries-in-dd","page":"Contributing","title":"Add/modify entries in dd","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The dd data structure is defined under the IMASdd.jl package. See the documentation there to how add/modify entries in dd.","category":"page"},{"location":"develop.html#Write-IMAS-physics-functions","page":"Contributing","title":"Write IMAS physics functions","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"IMAS physics and engineering functions are structured in IMAS.jl under IMAS/src/physics. These functions use or modify the datastructure (dd) in some way and are used to calculate certain quantities or fill the data structure.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Let's say we want to create a function that calculates the DT fusion and then fill core_sources with the alpha heating from that source. Here is an example of writing it in a good way:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function DT_fusion_source!(dd::IMAS.dd)\n return DT_fusion_source!(dd.core_sources, dd.core_profiles)\nend\n\n\"\"\"\n DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles)\n\nCalculates DT fusion heating with an estimation of the alpha slowing down to the ions and electrons, modifies dd.core_sources\n\"\"\"\nfunction DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles)\n # // actual implementation here //\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"convention: Convention\nThe documentation string is added to the specialized function DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles) and the dispatch function DT_fusion_source!(dd::IMAS.dd) is added on top of the function","category":"page"},{"location":"develop.html#Add/modify-entries-in-ini-and-act","page":"Contributing","title":"Add/modify entries in ini and act","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The functinoality of the ini and act parameters is implemented in the SimulationParameters.jl package.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The ini parameters are all defined in the FUSE/src/parameters_init.jl file. Add/edit entries there.\nThe act parameters of each actor are defined where that actor is defined. Add/edit entries there.","category":"page"},{"location":"develop.html#Write-a-new-actor","page":"Contributing","title":"Write a new actor","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Actors are grouped into two main abstract types:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"abstract type CompoundAbstractActor{D,P} <: AbstractActor{D,P} end\nabstract type SingleAbstractActor{D,P} <: AbstractActor{D,P} end","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"CompoundAbstractActors are for actors that compound multiple actors underneath and are initalized with ActorNAME(dd, par, act) while SingleAbstractActors are single actors initalized with ActorNAME(dd, par)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The definition of each FUSE actor follows a well defined pattern. DO NOT deviate from this pattern. This is important to ensure modularity and compostability of the actors.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"# Definition of the `act` parameters relevant to the actor\nBase.@kwdef mutable struct FUSEparameters__ActorNAME{T<:Real} <: ParametersActor{T}\n _parent::WeakRef = WeakRef(nothing)\n _name::Symbol = :not_set\n length::Entry{T} = Entry(T, \"m\", \"Some decription\") # it's ok not to have a default, it forces users to think about what a parameter should be\n verbose::Entry{Bool} = Entry(Bool, \"\", \"Some other decription\"; default=true)\n switch::Switch{Symbol} = Switch(Symbol, [:option_a, :option_b], \"\", \"user can only select one of these\"; default=:option_a)\nend\n\n# Defintion of the actor structure\n# NOTE: To be valid all actors must have `dd::IMAS.dd` and `par::FUSEparameters__ActorNAME`\nmutable struct ActorNAME <: ???AbstractActor\n dd::IMAS.dd\n par::FUSEparameters__ActorNAME # Actors must carry with them the parameters they are run with\n something_else::??? # Some actors may want to carry something else with them\n # Inner constructor for the actor starting from `dd` and `par` (we generally refer to `par` as `act.ActorNAME`)\n # NOTE: Computation should not happen here since in workflows it is normal to instantiate\n # an actor once `ActorNAME(dd, act.ActorNAME)` and then call `finalize(step(actor))` several times as needed.\n function ActorNAME(dd::IMAS.dd, par::FUSEparameters__ActorNAME; kw...)\n logging_actor_init(ActorNAME)\n par = par(kw...)\n return new(dd, par, something_else)\n end\nend\n\n# Constructor with with `dd` and `act` as arguments will actually run the actor!\n# That's how users will mostly run this actor.\n# This does not change, and it's always the same for all actors\n\"\"\"\n ActorNAME(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nWhat does this actor do...\n\"\"\"\nfunction ActorNAME(dd::IMAS.dd, act::ParametersAllActors; kw...)\n par = act.ActorNAME(kw...) # this makes a local copy of `act.ActorNAME` and overrides it with keywords that the user may have passed\n actor = ActorNAME(dd, par) # instantiate the actor (see function below)\n step(actor) # run the actor\n finalize(actor) # finalize\n return actor\nend\n\n# define `_step` function for this actor (this is where most of the action occurs)\n# note the leading underscore (use the `_step()` and not `step()` for the FUSE logging system to work with your actor)\n# `_step()` should not take any argument besides the actor itself\nfunction _step(actor::ActorNAME)\n ...\n return actor # _step() should always return the actor\nend\n\n# define `_finalize` function for this actor (this is where typically data gets written in `dd` if that does happen already at the `step`)\n# note the leading underscore (use the `_finalize()` and not `finalize()` for the FUSE logging system to work with your actor)\n# `_finalize()` should not take any argument besides the actor itself\nfunction _finalize(actor::ActorNAME)\n ...\n return actor # _finalize() should always return the actor\nend","category":"page"},{"location":"develop.html#Add-a-new-material","page":"Contributing","title":"Add a new material","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Material properties for supported fusion-relevant materials are stored in the FusionMaterials.jl package, specifically in FusionMaterials/src/materials.jl. Properties of each material can be accessed by calling the Material function with the material name as a symbol passed as the function argument. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To add a new material whose properties can be accessed in FUSE, first add a function to materials.jl called Material with the function argument being your material's name. In the body of the function, assign the material's name (as a string, all lowercase, and with any spaces filled by underscores), type (as a list containing each possible IMAS BuildLayerType the material could be assigned to), density (in kg/m^3) and unit cost (in US dollars per kilogram). Include a comment providing a link to the source from which the unit cost was taken. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Below is an example of a complete Material function for a non-superconductor material (more about superconductor materials below): ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function Material(::Type{Val{:graphite}};)\n\tmat = Material()\n\tmat.name = \"graphite\" # string with no spaces\n\tmat.type = [IMAS._wall_] # list of allowable layer types for this material\n\tmat.density = 1.7e3 # in kg/m^3\n\tmat.unit_cost = 1.3 # in US$/kg, include source as a comment # source: https://businessanalytiq.com/procurementanalytics/index/graphite-price-index/\n\treturn mat\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"If the material is a superconductor that is meant to be assigned to magnet-type layers, additional characteristics need to be defined. First, add the relevant critical current density scaling for the chosen superconductor material as a function in FusionMaterials/src/jcrit.jl. Then, assign the technology parameters for the material (temperature, steel fraction, void fraction, and ratio of superconductor to copper) to their respective fields in coiltech within the coiltechnology function in FUSE/src/technology.jl. Finally, call the critical current density scaling function within the newly written Material function in materials.jl and assign the output critical current density and critical magnetic field to the material object. The coil_tech object should be passed as an argument to the Material function, along with the external B field, and used to calculate the critical current density and critical magnetic field. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Below is an example of a complete superconductor Material function: ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function Material(::Type{Val{:rebco}}; coil_tech::Union{Missing, IMAS.build__pf_active__technology, IMAS.build__oh__technology, IMAS.build__tf__technology} = missing, Bext::Union{Real, Missing} = missing)\n\tmat = Material()\n\tmat.name = \"rebco\"\n\tmat.type = [IMAS._tf_, IMAS._oh_]\n\tmat.density = 6.3\n\tmat.unit_cost = 7000\n\n\tif !ismissing(coil_tech)\n\t\tJcrit_SC, Bext_Bcrit_ratio = ReBCO_Jcrit(Bext, coil_tech.thermal_strain + coil_tech.JxB_strain, coil_tech.temperature) # A/m^2\n\t\tfc = fraction_conductor(coil_tech)\n\t\tmat.critical_current_density = Jcrit_SC * fc\n\t\tmat.critical_magnetic_field = Bext / Bext_Bcrit_ratio\n\tend\n\n\treturn mat\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The function ReBCO_Jcrit is the critical current density function for this material. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"You can then access the parameters of your material by calling the function you've created. For example, access the material's density anywhere in FUSE by calling: ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"my_mat_density = Material(:my_mat).density","category":"page"},{"location":"develop.html#Profiling-and-writing-fast-Julia-code","page":"Contributing","title":"Profiling and writing fast Julia code","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"First let's do some profiling to identify problemetic functions:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Run FUSE from the VScode Julia REPL ( and then Julia: Start REPL)\nusing FUSE\nFUSE.logging(Logging.Info; actors=Logging.Info);\nini, act = FUSE.case_parameters(:FPP; version=:v1_demount, init_from=:scalars, STEP=true);\ndd = IMAS.dd()\nFUSE.init(dd, ini, act)\nFUSE.ActorWholeFacility(dd, act); # call this once to precompile\nnote: Note\n\nAlternatively one can create a profile.jl file in the FUSE/playground folder, write Julia code in that file, select the code to execute and run it with .\nUse @time to monitor execution time and allocations\nFor functions that return very quickly one can use BenchmarkTooks.@benchmark\nGraphical profiling of the execution time is a powerful way to understand where time is spent\n@profview FUSE.ActorWholeFacility(dd, act);\nwhere FUSE.ActorWholeFacility(dd, act); can really be any function that we care about\nLook at allocations\n@profview_allocs FUSE.ActorWholeFacility(dd, act);\nWe can decide how finely to comb for bottlenecks by setting sample_rate in @profview and @profview_allocs:\n@profview_allocs f(args...) [sample_rate=0.0001] [C=false]","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo move forward we have to understand how to write performant Julia code.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Let's now investigate where the issue is with the function that we have identified. For this we have several tools at our disposal:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"@code_warntype: static analyzer built-in with Julia\nonly looks at types that are inferred at runtime\nreports types only for the target function\n@code_warntype function()\nJET: static analyzer integrated with VScode\ncan detect different possible issues, including types inferred at runtime\nJET goes deep into functions\nJET.@report_opt function() reports dynamic dispatch\nJET.@report_call function() reports type errors\nJET.@report_call target_modules=(FUSE,IMAS,IMAS.IMASdd, ) FUSE.ActorNeutronics(dd,act);\nCthulhu: interactive static analyzer\nCthulhu.@descend function()","category":"page"},{"location":"develop.html#Build-the-documentation","page":"Contributing","title":"Build the documentation","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To build the documentation, in the FUSE/docs folder, start Julia then:\n] activate .\ninclude(\"make.jl\")\n!!! tip Interactive documentation build One can call include(\"make.jl\") over and over within the same Julia session to avoid dealing with startup time.\nCheck page by opening FUSE/docs/build/index.html page in web-browser.\nThe online documentation is built after each commit to master via GitHub actions.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nDocumentation files (PDF, DOC, XLS, PPT, ...) can be committed and pushed to the FUSE_extra_files repository, and then linked directly from within the FUSE documentation, like this:[video recording of the first FUSE tutorial](https://github.com/ProjectTorreyPines/FUSE_extra_files/raw/master/FUSE_tutorial_1_6Jul22.mp4)","category":"page"},{"location":"develop.html#Add/modify-examples","page":"Contributing","title":"Add/modify examples","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The FuseExamples repository contains jupyter notebook that showcase some possible uses of FUSE.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nWhen committing changes to in a jupyter notebook, make sure that all the output cells are cleared! This is important to keep the size of the repository in check.","category":"page"},{"location":"develop.html#Use-Revise.jl","page":"Contributing","title":"Use Revise.jl","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Install Revise.jl to modify code and use the changes without restarting Julia. We recommend adding import Revise to your ~/.julia/config/startup.jl to automatically import Revise at the beginning of all Julia sessions. This can be done by running:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"fusebot install_revise","category":"page"},{"location":"develop.html#Develop-in-VScode","page":"Contributing","title":"Develop in VScode","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"VScode is an excellent development environment for Julia.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"FUSE uses the following VScode settings for formatting the Julia code:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"{\n \"files.autoSave\": \"onFocusChange\",\n \"workbench.tree.indent\": 24,\n \"editor.insertSpaces\": true,\n \"editor.tabSize\": 4,\n \"editor.detectIndentation\": false,\n \"[julia]\": {\n \"editor.defaultFormatter\": \"julialang.language-julia\"\n },\n \"juliaFormatter.margin\": 160,\n \"juliaFormatter.alwaysForIn\": true,\n \"juliaFormatter.annotateUntypedFieldsWithAny\": false,\n \"juliaFormatter.whitespaceInKwargs\": false,\n \"juliaFormatter.overwriteFlags\": true,\n \"juliaFormatter.alwaysUseReturn\": true,\n}","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo add these settings to VScode add these lines to: + + p -> Preferences: Open User Settings (JSON)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo format Julia you will need to install Julia Language Support under the extensions tab ( + + x)","category":"page"},{"location":"develop.html#Track-Julia-precompilation","page":"Contributing","title":"Track Julia precompilation","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To see what is precompiled at runtime, you can add a Julia kernel with the trace-compile option to Jupyter","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"import IJulia\nIJulia.installkernel(\"Julia tracecompile\", \"--trace-compile=stderr\")","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Then select the Julia tracecompile in jupyter-lab","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nIf you want to remove jupyter kernels you don't use anymore you can list them first with jupyter kernelspec list and remove via jupyter kernelspec remove ","category":"page"},{"location":"develop.html#Run-Julia-within-a-Python-environment","page":"Contributing","title":"Run Julia within a Python environment","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"This can be particularly useful for benchmarking FUSE physics against existing Python routines (eg. in OMFIT)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Install PyCall in your Julia environment:\nexport PYTHON=\"\" # Sometimes one needs to empty the PYTHON environmental variable to install PyCall\njulia -e 'using Pkg; Pkg.add(\"PyCall\"); Pkg.build(\"PyCall\")'\nnote: Note\nPython and Julia must be compiled for the same architecture. For example, to install Julia x64 in a Apple Silicon MACs:juliaup add release~x64\nexport PYTHON=\"\"\njulia +release~x64 -e 'using Pkg; Pkg.add(\"PyCall\"); Pkg.build(\"PyCall\")'You can make this verison your default one withjuliaup default release~x64\nUse pip to install the package PyJulia — remember to use the same Python passed to ENV[\"PYTHON\"]:\npython3 –m pip install julia\nConfigure the communication between Julia and Python by running the following in the Python interpreter:\nimport julia\njulia.install()\nnote: Note\nIf you have more than one Julia version on our system, we could specify it with an argument:julia.install(julia=\"/Users/meneghini/.julia/juliaup/julia-1.8.5+0.x64.apple.darwin14/bin/julia\")\nTest the installation running the following in the Python interpreter run:\nfrom julia import Main\nMain.eval('[x^2 for x in 0:4]')\nNow, try something more useful:\nfrom julia.api import Julia\nJulia(compiled_modules=False)\ndef S(string): # from Python str to Julia Symbol\n return Main.eval(f\"PyCall.pyjlwrap_new({string})\")\n\nfrom julia import Main, IMAS, FUSE, Logging\nFUSE.logging(Logging.Info, actors=Logging.Debug);\n\nini, act = FUSE.case_parameters(S(\":FPP\"), version=S(\":v1_demount\"), init_from=S(\":scalars\"), STEP=True);\ndd = FUSE.init(ini, act);\n\neqt=dd.equilibrium.time_slice[-1]\ncp1d=dd.core_profiles.profiles_1d[-1]\njFUSE = IMAS.Sauter_neo2021_bootstrap(eqt, cp1d, neo_2021=True)","category":"page"},{"location":"install.html#Setup-the-FUSE-environment","page":"Install FUSE","title":"Setup the FUSE environment","text":"","category":"section"},{"location":"install.html#Julia-installation","page":"Install FUSE","title":"Julia installation","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"We highly recommend using the Juliaup manager to install Julia","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Mac & Linux: curl -fsSL https://install.julialang.org | sh\nWindows: winget install julia -s msstore","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Once installed, restart your termninal to pick-up the julia executable.","category":"page"},{"location":"install.html#FUSE-installation","page":"Install FUSE","title":"FUSE installation","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"FUSE and related packages are registered at the FuseRegistry. For installation start your Julia interpreter by typing julia at the terminal, then:","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Add the FuseRegistry and the FUSE package as you would for any other julia package (for a fresh install this can take 20+ mins):\nusing Pkg\nPkg.Registry.add(RegistrySpec(url=\"https://github.com/ProjectTorreyPines/FuseRegistry.jl.git\"))\nPkg.Registry.add(\"General\")\nPkg.add(\"FUSE\")\nNow you should be able to import the FUSE package:\nusing FUSE\nInstall the fusebot utility to simplify install/updates later on. Now fusebot should be a command that you can type anywhere from the terminal.\nFUSE.install_fusebot()\nRun the regression tests (optional, this can take 1h+)\njulia ] test FUSE\nExit julia and clone FUSE examples in the current working directory. To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.\nfusebot install_examples","category":"page"},{"location":"install.html#Keeping-FUSE-up-to-date","page":"Install FUSE","title":"Keeping FUSE up-to-date","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Get notified of new FUSE releases by \"watching\" the FUSE repo on GitHub\nFUSE is updated like any other Julia package:\njulia ] up","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"tip: Tip\nBecome familiar with how managing Julia packages works.","category":"page"},{"location":"install.html#Install-Jupyter-Lab-and-add-the-Julia-kernel-to-it","page":"Install FUSE","title":"Install Jupyter-Lab and add the Julia kernel to it","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"You will need to install jupyter-lab if that's not already available on your system \nInstall the IJulia package by running:\nfusebot install_IJulia\nnote: Note\nRun fusebot install_IJulia every time a new julia version is installed.This will setup the single- and multi-thread julia kernels in Jupyter.The number of threads of the multi-threaded julia kernels can be set via the JULIA_NUM_THREADS environmental variable.\nStart a new Jupyter-lab session (this should open a web-browser page with Jupyter running)\njupyter-lab\nNow you can browse the examples in the FuseExamples folder that you have cloned, and take a tour of the example Jupyter notebooks there.","category":"page"},{"location":"act.html#act-Parameters","page":"act parameters","title":"act Parameters","text":"","category":"section"},{"location":"act.html","page":"act parameters","title":"act parameters","text":"CurrentModule = FUSE","category":"page"},{"location":"act.html","page":"act parameters","title":"act parameters","text":"import FUSE # hide\nact = FUSE.ParametersActors()","category":"page"},{"location":"inits.html#Initialization","page":"Init routines","title":"Initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"CurrentModule = IMAS","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Recall that FUSE actors operate exclusively on IMAS.dd data. As such, to run any actor, one has to first initialize IMAS.dd with some data. This can be done in a number of ways:","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Manually/Interactivelly (eg. in the REPL or a Jupyter sesion)\nStarting from 0D ini and act parameters (same spirit of OMFIT's PRO_create module)\nBy reading in an existing OMAS JSON data structure with json2imas\nStarting from GA Systems Code output, then to ini, and finally to dd","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"The following init...() routines initialize dd from 0D parameters (method #2)","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"CurrentModule = FUSE","category":"page"},{"location":"inits.html#High-level-Initialization","page":"Init routines","title":"High-level Initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init","text":"init(\n dd::IMAS.dd,\n ini::ParametersAllInits,\n act::ParametersAllActors;\n do_plot::Bool=false,\n initialize_hardware::Bool=true,\n initialize_pulse_schedule::Bool=true,\n restore_expressions::Bool=true,\n verbose::Bool=false)\n\nInitialize dd starting from ini and act parameters\n\nFUSE provides this high-level init function to populate dd starting from the ini parameters.\n\nThis function essentially calls all other FUSE.init... functions in FUSE.\n\nFor most studies, calling this high level function is sufficient.\n\n\n\n\n\n","category":"method"},{"location":"inits.html#Use-cases-initialization","page":"Init routines","title":"Use-cases initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init(case::Symbol; do_plot:Bool=false, kw...)","category":"page"},{"location":"inits.html#FUSE.init-Tuple{Symbol}","page":"Init routines","title":"FUSE.init","text":"init(case::Symbol; do_plot::Bool=false, kw...)\n\nInitialize dd, ini, act based on a given use-case.\n\nReturns a tuple with dd, ini, act.\n\n\n\n\n\n","category":"method"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"","category":"page"},{"location":"inits.html#Low-level-initialization-routines","page":"Init routines","title":"Low-level initialization routines","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Below are the initialization functions specific to IDSs in the dd data structure. These can be called for a fine control on what IDSs are initialized and how.","category":"page"},{"location":"inits.html#balance-of-plant!","page":"Init routines","title":"balance of plant!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_balance_of_plant!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_balance_of_plant!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_balance_of_plant!","text":"init_balance_of_plant!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.balance_of_plant starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#build!","page":"Init routines","title":"build!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_build!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_build!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_build!","text":"init_build!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.build starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#core-profiles!","page":"Init routines","title":"core profiles!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_core_profiles!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_core_profiles!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_core_profiles!","text":"init_core_profiles!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.core_profiles starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#core-sources!","page":"Init routines","title":"core sources!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_core_sources!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_core_sources!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_core_sources!","text":"init_core_sources!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.nbi, dd.ec_launchers, dd.ic_antennas, dd.lh_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#currents!","page":"Init routines","title":"currents!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_currents!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_currents!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_currents!","text":"init_currents!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.core_profiles and dd.core_sources ohmic and bootstrap currents and sources starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#ec","page":"Init routines","title":"ec","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_ec(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_ec-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_ec","text":"init_ec(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.ec_launchers starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#equilibrium!","page":"Init routines","title":"equilibrium!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_equilibrium!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_equilibrium!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_equilibrium!","text":"init_equilibrium!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.equilibrium starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#expressions","page":"Init routines","title":"expressions","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_expressions(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#ic","page":"Init routines","title":"ic","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_ic(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_ic-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_ic","text":"init_ic(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.ic_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#lh","page":"Init routines","title":"lh","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_lh(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_lh-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_lh","text":"init_lh(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.lh_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#missing-from-ods!","page":"Init routines","title":"missing from ods!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_missing_from_ods!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_missing_from_ods!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_missing_from_ods!","text":"init_missing_from_ods!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize missing IDSs from ODS, only if ini.general.init_from == :ods.\n\n\n\n\n\n","category":"method"},{"location":"inits.html#nb","page":"Init routines","title":"nb","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_nb(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_nb-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_nb","text":"init_nb(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.nbi starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pf-active!","page":"Init routines","title":"pf active!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pf_active!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pf_active!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pf_active!","text":"init_pf_active!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.pf_active starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pl","page":"Init routines","title":"pl","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pl(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pl-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pl","text":"init_pl(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.pellet_launcher starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pulse-schedule!","page":"Init routines","title":"pulse schedule!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pulse_schedule!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pulse_schedule!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pulse_schedule!","text":"init_pulse_schedule!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd(); simplify_time_traces::Float64=0.1)\n\nInitialize dd.pulse_schedule starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pulse-schedule-postion-control","page":"Init routines","title":"pulse schedule postion control","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pulse_schedule_postion_control(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#requirements!","page":"Init routines","title":"requirements!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_requirements!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_requirements!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_requirements!","text":"init_requirements!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.requirements ini.requirements\n\n\n\n\n\n","category":"method"},{"location":"imas.html#Inner-workings-of-IMASdd.jl-and-IMAS.jl","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Inner workings of IMASdd.jl and IMAS.jl","text":"","category":"section"},{"location":"imas.html","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Inner workings of IMASdd.jl and IMAS.jl","text":"These two packages implement the functionalities of the ITER IMAS infrastructure in native Julia.","category":"page"},{"location":"imas.html#Data-types","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Data types","text":"","category":"section"},{"location":"imas.html#Expressions","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Expressions","text":"","category":"section"},{"location":"imas.html#Resizing-arrays-of-structures","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Resizing arrays of structures","text":"","category":"section"},{"location":"imas.html#Handling-of-time","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Handling of time","text":"","category":"section"},{"location":"ini.html#ini-Parameters","page":"ini parameters","title":"ini Parameters","text":"","category":"section"},{"location":"ini.html","page":"ini parameters","title":"ini parameters","text":"CurrentModule = FUSE","category":"page"},{"location":"ini.html","page":"ini parameters","title":"ini parameters","text":"import FUSE # hide\nini = FUSE.ParametersInits(; n_ic=1, n_nb=1, n_ec=1, n_lh=1, n_pl=1, n_layers=1)","category":"page"},{"location":"notice.html#FUSE.jl-Notice","page":"Notice","title":"FUSE.jl Notice","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"The purpose of this NOTICE file is to provide legal notices and acknowledgments that must be displayed to users in any derivative works or distributions. This file does not alter the terms of the Apache 2.0 license that governs the use and distribution of the FUSE.jl package.","category":"page"},{"location":"notice.html#Development-Attribution","page":"Notice","title":"Development Attribution","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"FUSE.jl was originally developed under the FUSE project by the Magnetic Fusion Energy group at General Atomics.","category":"page"},{"location":"notice.html#Citation","page":"Notice","title":"Citation","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"If this software contributes to an academic publication, please cite it as follows:","category":"page"},{"location":"notice.html","page":"Notice","title":"Notice","text":"@article{meneghini2024fuse,\nauthor = {Meneghini, O. and Slendebroek, T. and Lyons, B.C. and McLaughlin, K. and McClenaghan, J. and Stagner, L. and Harvey, J. and Neiser, T.F. and Ghiozzi, A. and Dose, G. and Guterl, J. and Zalzali, A. and Cote, T. and Shi, N. and Weisberg, D. and Smith, S.P. and Grierson, B.A. and Candy, J.},\ndoi = {10.48550/arXiv.2409.05894},\njournal = {arXiv},\ntitle = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}},\nyear = {2024}\n}","category":"page"},{"location":"notice.html#Trademark-Notice","page":"Notice","title":"Trademark Notice","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"The names \"General Atomics\", and any associated logos or images, are trademarks of General Atomics. Use of these trademarks without prior written consent from General Atomics is strictly prohibited. Users cannot imply endorsement by General Atomics or contributors to the project simply because the project is part of their work.","category":"page"},{"location":"notice.html#Copyright","page":"Notice","title":"Copyright","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"Copyright (c) 2024 General Atomics","category":"page"},{"location":"notice.html#Version","page":"Notice","title":"Version","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"Version: v2.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBalanceOfPlant.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.minimum_first_wall_thickness\nMinimum first wall thicknessType: Entry{Float64}\nUnits: m\nDefault: 0.02","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.blanket_multiplier\nNeutron thermal power multiplier in blanketType: Entry{Float64}\nUnits: -\nDefault: 1.2","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.thermal_power_extraction_efficiency\nFraction of thermal power that is carried out by the coolant at the blanket interface, rather than being lost in the surrounding strutures.Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.free_boundary\nConvert fixed boundary equilibrium to free boundary oneType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.clear_workdir\nClean the temporary workdir for CHEASEType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.rescale_eq_to_ip\nScale equilibrium to match IpType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCHEASE.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.rebuild_wall\nRebuild wall based on equilibriumType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.n_points\nNumber of points used for cross-sectional outlinesType: Entry{Int64}\nUnits: -\nDefault: 101","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.divertor_size\nDivertor size as fraction of plasma minor radiusType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.N\nNumber of launched photonsType: Entry{Int64}\nUnits: -\nDefault: 100000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.r\nVector of r at outermidplaneType: Entry{Vector{Float64}}\nUnits: m\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.q\nVector of parallel power density at outer midplaneType: Entry{Vector{Float64}}\nUnits: W m^-2\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.levels\nIf Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOLType: Entry{Union{Int64, Vector}}\nUnits: -\nDefault: 20","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.merge_wall\nMerge dd.wall in mesh for the heat flux Type: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.step\nStep for discretization of the default wall mesh (dd.wall)Type: Entry{Float64}\nUnits: m\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreTransport.model\nTransport actor to runType: Switch{Symbol}\nUnits: -\nOptions: FluxMatcher, EPEDProfiles, none\nDefault: FluxMatcher","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreTransport.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.model\nCosting modelType: Switch{Symbol}\nUnits: -\nOptions: ARIES, Sheffield\nDefault: ARIES","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.construction_start_year\nYear that plant construction beginsType: Entry{Int64}\nUnits: year\nDefault: 2024","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.future_inflation_rate\nPredicted average rate of future inflationType: Entry{Float64}\nUnits: -\nDefault: 0.025","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.plant_lifetime\nLifetime of the plantType: Entry{Int64}\nUnits: year\nDefault: 40","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.availability\nAvailability fraction of the plantType: Entry{Float64}\nUnits: -\nDefault: 0.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.production_increase\nFactor by which production of ReBCO multipliesType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.learning_rate\nLearning rate for ReBCO technology productionType: Entry{Float64}\nUnits: -\nDefault: 0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.land_space\nPlant site space requiredType: Entry{Float64}\nUnits: acres\nDefault: 1000.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.building_volume\nVolume of the tokmak buildingType: Entry{Float64}\nUnits: m^3\nDefault: 140000.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.interest_rate\nAnnual interest rate fraction of direct capital costType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.indirect_cost_rate\nIndirect cost associated with construction, equipment, services, engineering construction management and owners costType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.escalation_fraction\nYearly escalation fraction based on risk assessmentType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.blanket_lifetime\nLifetime of the blanketType: Entry{Float64}\nUnits: year\nDefault: 6.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.construction_lead_time\nDuration of constructionType: Entry{Float64}\nUnits: year\nDefault: 8.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.fixed_charge_rate\nConstant dollar fixed charge rateType: Entry{Float64}\nUnits: -\nDefault: 0.078","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.capitalize_blanket\nIf true, include cost of 1st blanket in direct captial costType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.capitalize_divertor\nIf true, include cost of 1st divertor in direct captial costType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.divertor_fluence_lifetime\nDivertor fluence over its lifetimeType: Entry{Float64}\nUnits: MW*yr/m²\nDefault: 10.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.blanket_fluence_lifetime\nBlanket fluence over its lifetimeType: Entry{Float64}\nUnits: MW*yr/m²\nDefault: 15.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCurrent.model\nCurrent actor to runType: Switch{Symbol}\nUnits: -\nOptions: SteadyStateCurrent, QED, none\nDefault: SteadyStateCurrent","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCurrent.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCurrent.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCurrent.vloop_from\nTake vloop from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule, controllers__ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.heat_flux_model\nDivertor heat flux modelType: Switch{Symbol}\nUnits: -\nOptions: lengyel, stangeby\nDefault: lengyel","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.impurities\nVector of impurity speciesType: Entry{Vector{Symbol}}\nUnits: -\nDefault: Symbol[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.impurities_fraction\nVector of impurity fractionsType: Entry{Vector{Float64}}\nUnits: -\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.heat_spread_factor\nHeat flux expansion factor in the private flux region (eg. due to transport) should be >= 1.0Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.thermal_power_extraction_efficiency\nFraction of thermal power that is carried out by the coolant at the divertor interface, rather than being lost in the surrounding strutures.Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorDynamicPlasma.Δt\nEvolve for ΔtType: Entry{Float64}\nUnits: s","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorDynamicPlasma.Nt\nNumber of time steps during evolutionType: Entry{Int64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_transport\nEvolve the transportType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_pedestal\nEvolve the pedestalType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_hcd\nEvolve the heating and current driveType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_current\nEvolve the plasma currentType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_equilibrium\nEvolve the equilibriumType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_pf_active\nEvolve the PF currentsType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.ip_controller\nUse controller to change v_loop to match desired IpType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.time_derivatives_sources\nInclude time-derivative sourcesType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.rho_nml\nDefines rho at which the no man's land region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.rho_ped\nDefines rho at which the pedestal region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.T_ratio_pedestal\nRatio of ion to electron temperatures (or rho at which to sample for that ratio, if negative; or rhonml-(rhoped-rho_nml) if 0.0)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.ped_factor\nPedestal height multiplier (width scaled by sqrt of this factor)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.only_powerlaw\nEPED-NN uses power-law pedestal fit (without NN correction)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.βn_from\nTake βn from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.ne_ped_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.warn_nn_train_bounds\nEPED-NN raises warnings if querying cases that are certainly outside of the training rangeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_shaping\nShaping coefficient for the temperature profileType: Entry{Float64}\nUnits: -\nDefault: 1.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.ne_shaping\nShaping coefficient for the density profileType: Entry{Float64}\nUnits: -\nDefault: 1.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_ratio_pedestal\nIon to electron temperature ratio in the pedestalType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_ratio_core\nIon to electron temperature ratio in the coreType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.model\nEquilibrium actor to runType: Switch{Symbol}\nUnits: -\nOptions: Solovev, CHEASE, TEQUILA\nDefault: TEQUILA","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.symmetrize\nForce equilibrium up-down symmetry with respect to magnetic axisType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.j_p_from\nTake j_tor and pressure profiles from this IDSType: Switch{Symbol}\nUnits: -\nOptions: equilibrium, core_profiles\nDefault: core_profiles","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEquilibrium.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.vacuum_r0_b0_from\nTake vacuumr0b0 from this IDSType: Switch{Symbol}\nUnits: -\nOptions: equilibrium, pulse_schedule\nDefault: pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.rho_transport\nrho core transport gridType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.turbulence_model\nTurbulence model to useType: Switch{Symbol}\nUnits: -\nOptions: TGLF, QLGYRO, none\nDefault: TGLF","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.neoclassical_model\nNeocalssical model to useType: Switch{Symbol}\nUnits: -\nOptions: neoclassical, none\nDefault: neoclassical","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.rho_transport\nρ transport gridType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_Ti\nIon temperature :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_Te\nElectron temperature :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_densities\nDensities :fixed, or electron flux-match and rest match ne scale :flux_match, or Dict to specify which species are :flux_match, kept :fixed, used to enforce :quasi_neutrality, or scaled to :match_ne_scaleType: Entry{Union{Symbol, AbstractDict}}\nUnits: -\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_rotation\nRotation :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: fixed","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_pedestal\nEvolve the pedestal within the transport solverType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.find_widths\nRuns turbulent transport actor TJLF finding widths after first iterationType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.max_iterations\nMaximum optimizer iterationsType: Entry{Int64}\nUnits: -\nDefault: 500","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.optimizer_algorithm\nOptimizing algorithm used for the flux matchingType: Switch{Symbol}\nUnits: -\nOptions: anderson, newton, trust_region, simple, none\nDefault: anderson","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.step_size\nStep size for each algorithm iteration (note this has a different meaning for each algorithm)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.Δt\nEvolve for Δt (Inf for steady state)Type: Entry{Float64}\nUnits: s\nDefault: Inf","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.save_input_tglf_folder\nSave the intput.tglf files in designated folder at the last iterationType: Entry{String}\nUnits: -\nDefault: ``","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.relax\nRelaxation on the final solutionType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorFluxMatcher.norms\nRelative normalization of different channelsType: Entry{Vector{Float64}}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxSwing.operate_oh_at_j_crit\nIf true it makes the OH operate at its current limit (within specified dd.requirements.coiljmargin`).","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"The flattop duration and maximum toroidal magnetic field follow from that. Otherwise we evaluate what is the current needed for dd.requirements.flattopduration, which may or may not exceed the OH critical current limit. If dd.requirements.flattopduration is not set, then operateohatjcrit is assumed. * Type: Entry{Bool} * Units: - * Default: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.ec_model\nEC source actor to runType: Switch{Symbol}\nUnits: -\nOptions: ECsimple, none\nDefault: ECsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.ic_model\nIC source actor to runType: Switch{Symbol}\nUnits: -\nOptions: ICsimple, none\nDefault: ICsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.lh_model\nLH source actor to runType: Switch{Symbol}\nUnits: -\nOptions: LHsimple, none\nDefault: LHsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.nb_model\nNB source actor to runType: Switch{Symbol}\nUnits: -\nOptions: NBsimple, RABBIT, none\nDefault: NBsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.pellet_model\nPellet source actor to runType: Switch{Symbol}\nUnits: -\nOptions: Pelletsimple, none\nDefault: Pelletsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.error_on_technology\nError if build stresses and current limits are not metType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.error_on_performance\nError if requested Bt and flattop duration are not metType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.maintenance\nScheme for installation/removal of in-vessel componentsType: Switch{Symbol}\nUnits: -\nOptions: vertical, horizontal, none\nDefault: none","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.tor_modularity\nNumber of toroidal modules of blanket normalized to number of TF coilsType: Entry{Int64}\nUnits: -\nDefault: 2","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.pol_modularity\nNumber of poloidal modules of each toroidal blanket sectorType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNBI.model\nNBI modelType: Switch{Symbol}\nUnits: -\nOptions: simple, RABBIT\nDefault: simple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeoclassical.model\nNeoclassical model to runType: Switch{Symbol}\nUnits: -\nOptions: changhinton, neo, hirshmansigmar\nDefault: hirshmansigmar","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeoclassical.rho_transport\nrhotornorm values to compute neoclassical fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeutronics.N\nNumber of particlesType: Entry{Int64}\nUnits: -\nDefault: 100000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeutronics.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.green_model\nModel used for the coils Green function calculationsType: Switch{Symbol}\nUnits: -\nOptions: point, quad\nDefault: quad","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.update_equilibrium\nOverwrite target equilibrium with the one that the coils can actually makeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.symmetric\nForce PF coils location to be up-down symmetricType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.update_equilibrium\nOverwrite target equilibrium with the one that the coils can actually makeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.model\nCoil placement strategyType: Switch{Symbol}\nUnits: -\nOptions: none, uniform, optimal\nDefault: optimal","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.r\nVector of r at outermidplaneType: Entry{Vector{Float64}}\nUnits: m\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.q\nVector of parallel power density at outer midplaneType: Entry{Vector{Float64}}\nUnits: W m^-2\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.levels\nIf Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOLType: Entry{Union{Int64, Vector{Float64}}}\nUnits: -\nDefault: 20","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.merge_wall\nMerge dd.wall in mesh for the heat flux Type: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.step\nStep for discretization of the default wall mesh (dd.wall)Type: Entry{Float64}\nUnits: m\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.wall_precision\nPrecision for making wall quadralateralsType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.min_n_segments\nMinimum number of quadralateralsType: Entry{Int64}\nUnits: -\nDefault: 15","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.rho_nml\nDefines rho at which the no man's land region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.rho_ped\nDefines rho at which the pedestal region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.density_match\nMatching density based on ne_ped or line averaged densityType: Switch{Symbol}\nUnits: -\nOptions: ne_line, ne_ped\nDefault: ne_ped","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.model\nPedestal model to useType: Switch{Symbol}\nUnits: -\nOptions: EPED, WPED, auto, none\nDefault: EPED","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.βn_from\nTake βn from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.ne_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPowerNeeds.model\nPower plant electrical needs modelType: Switch{Symbol}\nUnits: -\nOptions: thermal_power_fraction, EU_DEMO, FUSE\nDefault: FUSE","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPowerNeeds.thermal_power_fraction\nFraction of the gross electrical power generated by the thermal cycle (if model==:thermal_power_fraction)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPowerNeeds.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.Δt\nEvolve for Δt (Inf for steady state)Type: Entry{Float64}\nUnits: s\nDefault: Inf","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.Nt\nNumber of time steps during evolutionType: Entry{Int64}\nUnits: -\nDefault: 100","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.solve_for\nSolve for specified Ip or VloopType: Switch{Symbol}\nUnits: -\nOptions: ip, vloop\nDefault: ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.vloop_from\nTake vloop from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule, controllers__ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.model\nImplementation of QLGYROType: Switch{Symbol}\nUnits: -\nOptions: QLGYRO\nDefault: QLGYRO","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.ky\nMax kyType: Entry{Float64}\nUnits: -\nDefault: 1.6","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.nky\nNumber of ky modesType: Entry{Int64}\nUnits: -\nDefault: 16","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.cpu_per_ky\nNumber of cpus per kyType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.kygrid_model\nTGLF ky grid modelType: Entry{Int64}\nUnits: -\nDefault: 0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.sat_rule\nSaturation ruleType: Switch{Symbol}\nUnits: -\nOptions: sat1, sat2, sat3\nDefault: sat1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.n_field\n1:phi, 2:phi+apar, 3:phi+apar+bparType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.delta_t\nCGYRO step size Type: Entry{Float64}\nUnits: -\nDefault: 0.005","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.max_time\nMax simulation time (a/cs)Type: Entry{Float64}\nUnits: -\nDefault: 100.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.rho_transport\nrhotornorm values to compute QLGYRO fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.lump_ions\nLumps the fuel species (D,T) as well as the impurities togetherType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleEC.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleIC.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleLH.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleNB.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.ngrid\nGrid size (for R, Z follows proportionally to plasma elongation)Type: Entry{Int64}\nUnits: -\nDefault: 129","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.qstar\nInitial guess of kink safety factorType: Entry{Float64}\nUnits: -\nDefault: 1.5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.alpha\nInitial guess of constant relating to pressureType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSolovev.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStabilityLimits.models\nModels used for checking plasma stability limits: [:densitylimits, :betalimits, :currentlimits, :defaultlimits, :unknown, :κcontrollability, :betamodel105, :q95gt2, :betabernard1983, :gwdensity, :betatuda1985, :betatroyon1985, :q08gt2, :betatroyon1984]Type: Entry{Vector{Symbol}}\nUnits: -\nDefault: [:default_limits]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStabilityLimits.raise_on_breach\nRaise an error when one or more stability limits are breachedType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.max_iter\nmax number of transport-equilibrium iterationsType: Entry{Int64}\nUnits: -\nDefault: 5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.convergence_error\nConvergence error threshold (relative change in current and pressure profiles)Type: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSteadyStateCurrent.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSteadyStateCurrent.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStresses.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStresses.n_points\nNumber of grid pointsType: Entry{Int64}\nUnits: -\nDefault: 5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.free_boundary\nConvert fixed boundary equilibrium to free boundary oneType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_radial_grid_points\nNumber of TEQUILA radial grid pointsType: Entry{Int64}\nUnits: -\nDefault: 31","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_fourier_modes\nNumber of modes for Fourier decompositionType: Entry{Int64}\nUnits: -\nDefault: 8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_MXH_harmonics\nNumber of Fourier harmonics in MXH representation of flux surfacesType: Entry{Int64}\nUnits: -\nDefault: 4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_iterations\nNumber of TEQUILA iterationsType: Entry{Int64}\nUnits: -\nDefault: 1000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.relax\nRelaxation on the Picard iterationsType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.tolerance\nTolerance for terminating iterationsType: Entry{Float64}\nUnits: -\nDefault: 0.0001","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.fixed_grid\nFix P and Jt on this rho gridType: Switch{Symbol}\nUnits: -\nOptions: poloidal, toroidal\nDefault: toroidal","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.debug\nPrint debug information withing TEQUILA solveType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.R\nPsi R axisType: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.Z\nPsi Z axisType: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.model\nImplementation of TGLFType: Switch{Symbol}\nUnits: -\nOptions: TGLF, TGLFNN, TJLF\nDefault: TGLFNN","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.sat_rule\nSaturation ruleType: Switch{Symbol}\nUnits: -\nOptions: sat0, sat0quench, sat1, sat1geo, sat2, sat3\nDefault: sat1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.electromagnetic\nElectromagnetic or electrostaticType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.user_specified_model\nUse a user specified TGLF-NN model stored in TGLFNN/modelsType: Entry{String}\nUnits: -\nDefault: ``","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.rho_transport\nrhotornorm values to compute tglf fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.warn_nn_train_bounds\nRaise warnings if querying cases that are certainly outside of the training rangeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTGLF.custom_input_files\nSets up the input file that will be run with the custom input file as a maskType: Entry{Union{Vector{<:TGLFNN.InputTGLF}, Vector{<:TJLF.InputTJLF}}}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.lump_ions\nLumps the fuel species (D,T) as well as the impurities togetherType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.model\nPower plant heat cycle efficiencyType: Switch{Symbol}\nUnits: -\nOptions: fixed_plant_efficiency, network, surogate\nDefault: surogate","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.fixed_plant_efficiency\nOverall thermal cycle efficiency (if model=:fixed_plant_efficiency)Type: Entry{Float64}\nUnits: -\nDefault: 0.35","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorVerticalStability.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.ped_to_core_fraction\nRatio of edge (@rho=0.9) to core stored energy [0.05 for L-mode, 0.3 for neg-T plasmas]Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.rho_ped\nDefines rho at which the edge region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.ne_ped_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWPED.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWholeFacility.update_plasma\nRun plasma related actorsType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWholeFacility.update_build\nOptimize tokamak buildType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"amns_data.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].extrapolation_type\nExtrapolation strategy when leaving the domain. The first value of the vector describes the behaviour at lower bound, the second describes the at upper bound. Possible values: 0=none, report error; 1=boundary value; 2=linear extrapolationData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].interpolation_type\nInterpolation strategy in this coordinate direction. Integer flag: 0=discrete (no interpolation); 1=linear; ...Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].label\nDescription of coordinate (e.g. \"Electron temperature\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].spacing\nFlag for specific coordinate spacing (for optimization purposes). Integer flag: 0=undefined; 1=uniform; ...Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].transformation\nCoordinate transformation applied to coordinate values stored in coord. Integer flag: 0=none; 1=log10; 2=lnData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].units\nUnits of coordinate (e.g. eV)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].value_labels\nString description of discrete coordinate values (if interpolation_type=0). E.g., for spectroscopic lines, the spectroscopic description of the transition.Data Type: STR_1D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].values\nCoordinate valuesUnits: units given by coordinate_system(:)/coordinate(:)/units\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_0d\n0D table describing the process dataUnits: units given by process(:)/results_units\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_1d\n1D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_1D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_2d\n2D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_2D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_3d\n3D table describing the process dataUnits: units given by process(:)/results_units\nData Type: FLT_3D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_4d\n4D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_4D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_5d\n5D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_5D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_6d\n6D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_6D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].citation\nReference to publication(s)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].coordinate_index\nIndex in tables_coord, specifying what coordinate systems to use for this process (valid for all tables)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].label\nString identifying the process (e.g. EI, RC, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].charge\nCharge number of the participantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].label\nString identifying reaction participant (e.g. \"D\", \"e\", \"W\", \"CD4\", \"photon\", \"n\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].mass\nMass of the participantUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].metastable\nAn array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].metastable_label\nLabel identifying in text form the metastableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].multiplicity\nMultiplicity in the reactionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].relative_charge\nThis is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundleData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].charge\nCharge number of the participantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].label\nString identifying reaction participant (e.g. \"D\", \"e\", \"W\", \"CD4\", \"photon\", \"n\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].mass\nMass of the participantUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].metastable\nAn array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].metastable_label\nLabel identifying in text form the metastableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].multiplicity\nMultiplicity in the reactionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].relative_charge\nThis is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundleData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_label\nDescription of the process result (rate, cross section, sputtering yield, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_transformation\nTransformation of the process result. Integer flag: 0=no transformation; 1=10^; 2=exp()Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_units\nUnits of the process resultData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].source\nFilename or subroutine name used to provide this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].table_dimension\nTable dimensionality of the process (1 to 6), valid for all charge states. Indicates which of the tables is filled (below the charge_state node)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].description\nDescription of this data entryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].run\nWhich run number is the active run number for this versionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].shot\nShot number = Mass*1000+Nuclear_chargeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].date\nDate of this releaseData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].description\nDescription of this releaseData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"b_field_non_axisymmetric.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.configuration\nIn case of a constant (single time slice) b_field description, name of the corresponding scenario/configurationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.control_surface_names\nList of control surface names, refers to the ../timeslice/controlsurface indexData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal\nNormal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal_fourier\nFourier coefficients of the normal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: CPX_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_r\nR component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_tor\nToroidal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_z\nZ component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor\nToroidal mode numberData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\nToroidal angle array, on which the Fourier decomposition is carried outUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_r\nR component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_tor\nToroidal component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_z\nZ component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.ripple_amplitude\nValue of (bfieldmax-bfieldmin)/(bfieldmax+bfieldmin), where bfieldmax resp. bfieldmin) is the maximum (resp. minimum) of the magnetic field amplitude over a 2pi rotation in toroidal angle phi at a given R, Z position. Data Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.Q_plant\nElectricity gain of the plant (ratio of net electric / plant electricity during operation)Data Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_net\nNet electric powerUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].power\nElectrical power used to operate the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].power\nElectrical power used to operate the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.total_power\nTotal Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.generator_conversion_efficiency\nConversion efficiency of thermal to electric power of the steam cycleData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.breeder\nThe heat flow towards the breeder.Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.divertor\nThe heat flow towards the divertorUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.wall\nThe heat flow towards the wall.Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.power_cycle_type\nType of primary power cycle, :brayton = gas, :rankine = steamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.power_electric_generated\nThe net electric power produced by the thermal plant, equal tot the power produced by turbines LESS the power consumed by pumps and compressorsUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].name\nName of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].massflow\nMass Flow Rate of the fluidUnits: kg/s\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].mechanicalPower\nShaft power associated with the component, (+) = into the system, (-) = out of the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].name\nName of the portData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].pressure\nFluid pressureUnits: Bar\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].temperature\nFluid TemperatureUnits: C\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].thermalPower\nHeattransfer rate of the component, (+) = into the system, (-) = out of the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.total_heat_rejected\nThe total heat flow being rejected from the thermal plantUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.total_heat_supplied\nThe total heat flow being supplied to the thermal Plant (Fusion thermal power).Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.thermal_efficiency_cycle\nThe fractional thermal effiency of the power cycle. Calculated as 1-Qout/QinData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.thermal_efficiency_plant\nThe fractional thermal effiency of the entire BOP thermal plant, inlcudes all of the individual cycles. Calculated as 1-Qout/QinData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"barometry.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].calibration_coefficient\nCoefficient used for converting raw signal into absolute pressureUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].name\nName of the gaugeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].pressure.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"barometry.gauge[:].pressure.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].pressure.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].material\nMaterial of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].midplane_thickness\nThickness of layer evaluated at the midplaneUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].name\nName of the blanket layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].name\nName of the blanket moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].peak_escape_flux\nMaximum neutron flux escaping from the back of the blanket moduleUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].peak_wall_flux\nMaximum neutron flux at the first wallUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_incident_neutrons\nTotal incident neutron power on the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_incident_radiated\nTotal incident radiative power on the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_extracted\nTotal thermal power that is extracted from the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_neutrons\nTotal neutron power (deposited + generated) in the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_radiated\nTotal radiated power (incident - reflected) in the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].tritium_breeding_ratio\nNumber of tritium atoms for each incident neutron (TBR)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.tritium_breeding_ratio\nNumber of tritium atoms created for each fusion neutron (TBR)Data Type: FLT_1D\nCoordinates: [\"blanket.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].power.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].power.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity\nIndicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity_timed.data\nDataData Type: INT_1D\nCoordinates: [\"bolometer.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.volume_element\nVolume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"bolometer.grid.dim1\", \"bolometer.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_density.data\nDataUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"bolometer.grid.dim1\", \"bolometer.grid.dim2\", \"bolometer.power_density.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_density.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_inside_lcfs\nRadiated power from the plasma inside the Last Closed Flux Surface, reconstructed from bolometry dataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_total\nTotal radiated power reconstructed from bolometry dataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_validity\nValidity flag related to the radiated power reconstructionsData Type: INT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].filter.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].intensity.data\nDataUnits: (counts) s^-1\nData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.data\nDataData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"bremsstrahlung_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.divertors.lower.installed\n1 if a lower divertor is installedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.divertors.upper.installed\n1 if a upper divertor is installedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.flattop\nTotal flux required for the plasma flattopUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.pf\nContribution of vertical field from PF coils to flux swingUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.rampup\nTotal flux required for the plasma rampupUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].area\nCross sectional area of the layerUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].end_radius\nEnd radius of the layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].identifier\nInteger to identify the same layer on the high-field-side and low-field-sideData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].material\nMaterial of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].name\nName of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.layer[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].shape\nInteger to identify the physical shape of the layerData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].shape_parameters\nList of the shape specific parameters for given shape typeData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].side\nInteger set to -1 if layer is on the low-field-side and 1 if layer is on the high-field-side. 0 for plasma. 2 for inner (eg. OH) and 3 for outer (eg. cryostat)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].start_radius\nStart radius of the layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].thickness\nRadial thickness of layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].type\nLayer type code","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"vacuum (use this to set mimimum radius for OH)\nOH\nTF\nBL\nShielding\nWall","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"-1) Vacuum vessel * Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].volume\nVolume of the layerUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].volume_no_structures\nVolume of the layer without structuresUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.critical_b_field\nCritical magnetic field density to quench superconducting OHUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.critical_j\nCritical current density to quench superconducting OHUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.flattop_duration\nEstimated duration of the flattopUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.max_b_field\nMaximum magnetic field in the OH solenoid, as required to satisfy rampup and flattop flux consumptionUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.max_j\nMaximum current density in the OH solenoid, as required to satisfy rampup and flattop flux consumptionUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.fraction_steel\nFraction of stainless steel in the OH coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.fraction_void\nFraction of void in the OH coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.material\nMaterial of the OH coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.temperature\nOH coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].coils_cleareance\nClereance that coils have from other structuresUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].coils_number\nNumber of coils on the railData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].name\nName of the coil railData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.distance\nDistance along the rail skipping gapsUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.pf_active.rail[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.pf_active.rail[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.fraction_steel\nFraction of stainless steel in the PF coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.fraction_void\nFraction of void in the PF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.material\nMaterial of the PF coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.temperature\nPF coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].area\nCross sectional area of the structureUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].identifier\nString to identify structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].material\nMaterial of the structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].name\nName of the structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.structure[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].toroidal_angles\nToroidal position(s) of the structureUnits: rad\nData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].toroidal_extent\nToroidal extent of the structureUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].type\nStructure type codeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].volume\nVolume of the structureUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.coils_n\nNumber of TF coils around the torusData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.critical_b_field\nCritical magnetic field to quench superconducting TFUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.critical_j\nCritical current density to quench superconducting TFUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.max_b_field\nMaximum magnetic field evaluated at the TF high-field sideUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.max_j\nMaximum current density in the TF solenoidUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.ripple\nFraction of toroidal field ripple evaluated at the outermost radius of the plasma chamberData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.fraction_steel\nFraction of stainless steel in the TF coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.fraction_void\nFraction of void in the TF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.material\nMaterial of the TF coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.temperature\nTF coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.wedge_thickness\nThickness of the TF coils wedge evaluatedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"calorimetry.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].identifier\nID of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.data\nDataUnits: kg.s^-1\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].name\nName of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.data\nDataUnits: J\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].energy_cumulated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].energy_cumulated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_total.data\nDataUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_total.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].identifier\nID of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.data\nDataUnits: kg.s^-1\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].name\nName of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].transit_time.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].transit_time.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].identifier\nID of the groupData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].name\nName of the groupData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.luminance_to_temperature\nLuminance to temperature conversion tableData Type: INT_2D\nCoordinates: [\"1...N\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.optical_temperature\nTemperature of the optical components (digital levels)Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_barrel\nTransmission of the optical barrelData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_mirror\nTransmission of the mirrorData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_window\nTransmission of the windowData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_ir.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame[:].surface_temperature\nSurface temperature image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis). The size of this matrix is assumed to be constant over timeUnits: K\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].distance_separatrix_midplane\nDistance between the measurement position and the separatrix, mapped along flux surfaces to the outboard midplane, in the major radius direction. Positive value means the measurement is outside of the separatrix.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].power_flux_parallel\nParallel heat flux received by the element monitored by the camera, along the distanceseparatrixmidplane coordinateUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"camera_ir.frame_analysis[:].distance_separatrix_midplane\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].sol_heat_decay_length\nHeat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].columns_n\nNumber of pixel columns in the horizontal directionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].counts_to_radiance\nCounts to radiance factor, for each pixel of the detector. Includes both the transmission losses in the relay optics and the quantum efficiency of the camera itself, integrated over the wavelength rangeUnits: photons.m^-2.s^-1.sr^-1.counts^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].image_raw\nRaw image (unprocessed) (digital levels). First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].radiance\nRadiance image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Units: photons.m^-2.s^-1.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3\nThird dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.data\nInterpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector pixel). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi (third dimension of this array). The first two dimension correspond to the detector pixels : first dimension : line index (horizontal axis); second dimension: column index (vertical axis). Units: m^-2\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.phi\nToroidal angle (oriented counter-clockwise when viewing from above) of interpolation knotsUnits: rad\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\nMajor radius of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.z\nHeight of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.voxel_map\nVoxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.Data Type: INT_3D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1\", \"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2\", \"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.voxels_n\nNumber of voxels defined in the voxel_map.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.pixel_indices\nList of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.pixel_indices\nList of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].lines_n\nNumber of pixel lines in the vertical directionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].noise\nDetector noise (e.g. read-out noise) (rms counts per second exposure time)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].pixel_to_alpha\nAlpha angle of each pixel in the horizontal axisUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].pixel_to_beta\nBeta angle of each pixel in the vertical axisUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].wavelength_lower\nLower bound of the detector wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].wavelength_upper\nUpper bound of the detector wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].viewing_angle_alpha_bounds\nMinimum and maximum values of alpha angle of the field of view, where alpha is the agle between the axis X3 and projection of the chord of view on the plane X1X3 counted clockwise from the top view of X2 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].viewing_angle_beta_bounds\nMinimum and maximum values of beta angle of the field of view, where beta is the angle between the axis X3 and projection of the chord of view on the plane X2X3 counted clockwise from the top view of X1 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.camera_dimensions\nTotal camera dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.identifier\nID of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_dimensions\nPixel dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixels_n\nNumber of pixels in each direction (x1, x2)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_x_rays.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_humidity.data\nDataData Type: FLT_1D\nCoordinates: [\"camera_x_rays.detector_humidity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_humidity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_temperature.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.detector_temperature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_temperature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.energy_configuration_name\nName of the chosen energy configuration (energy detection threshold)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.energy_threshold_lower\nLower energy detection threshold on each pixel of the detector (photons are counted only if their energy is above this value)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.filter_window.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"camera_x_rays.filter_window.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.frame[:].counts_n\nNumber of counts detected on each pixel during one exposure time. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.photon_energy\nList of values of the photon energy (coordinate for quantum_effiency)Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.pixel_status\nStatus of each pixel : +1 for valid pixels, -1 for inactive pixels, -2 for mis-calibrated pixels. Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.quantum_efficiency\nQuantum efficiency of the detector, i.e. conversion factor multiplying the number of counts to obtain the number of photons impacting the detector, tabulated as a function of the photon energy, for each pixel of the detector. If all pixels have the same quantum efficiency, just set the size of the first and second dimensions to 1Data Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"camera_x_rays.photon_energy\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.readout_time\nTime used to read out each frame on the detectorUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.a\nMass of atom of the diagnostic neutral beam particleUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.doppler_shift.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].bes.doppler_shift.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.doppler_shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.label\nString identifying the diagnostic neutral beam particleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.lorentz_shift.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].bes.lorentz_shift.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.lorentz_shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.radiances.data\nDataUnits: (photons) m^-2.s^-1.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].bes.radiances.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.radiances.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.transition_wavelength\nUnshifted wavelength of the BES transitionUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.z_ion\nIon charge of the diagnostic neutral beam particleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].processed_line[:].width.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].spectrum[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_continuum.data\nDataUnits: m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].spectrum[:].radiance_continuum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_continuum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_spectral.data\nDataUnits: (photons) m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].spectrum[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].slit_width\nWidth of the slit (placed in the object focal plane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].t_i_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff.data\nDataData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].zeff.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average.data\nDataData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"charge_exchange.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue\nEtendue (geometric extent) of the optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].conductor[:].elements.types\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].conductor[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].conductor[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"controllers.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].data\nArray of scalar metrics in time Data Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].time\nControlability metric timeUnits: s\nData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].controller_class\nOne of a known class of controllersData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].description\nDescription of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].input_names\nNames of the input signals, following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].inputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.linear_controller[:].inputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].inputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].name\nName of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].output_names\nNames of the output signals following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].outputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.linear_controller[:].outputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].outputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.d.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.d.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.d.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.i.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.i.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.i.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.p.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.p.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.p.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.tau.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"controllers.linear_controller[:].pid.tau.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.tau.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.a.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].statespace.a.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.a.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.b.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].statespace.b.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.b.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.c.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].statespace.c.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.c.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.d.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].statespace.d.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.d.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.deltat.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"controllers.linear_controller[:].statespace.deltat.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.deltat.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.state_names\nNames of the statesData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].controller_class\nOne of a known class of controllersData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].description\nDescription of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].function\nMethod to be definedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].input_names\nNames of the input signals, following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].inputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.nonlinear_controller[:].inputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].inputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].name\nName of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].output_names\nOutput signal names following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].outputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.nonlinear_controller[:].outputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].outputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_instant_changes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.data\nCovariance matrixUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"core_profiles.covariance.rows_uri\", \"core_profiles.covariance.rows_uri\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.description\nDescription of this covariance matrixData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.rows_uri\nList of URIs corresponding to the rows (1st dimension) of the covariance matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector it is sufficient to give a single URI where this vector is denoted using the (:) implicit notation, e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_pol\nPoloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_tor\nToroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_tor_norm\nNormalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA] Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_bootstrap\nBootstrap current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_non_inductive\nTotal non-inductive current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_ohmic\nOhmic current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ejima\nEjima coefficient : resistive psi losses divided by (mu0RIp). See S. Ejima et al, Nuclear Fusion, Vol.22, No.10 (1982), 1313Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.energy_diamagnetic\nPlasma energy content = 3/2 * integral over the plasma volume of the total perpendicular pressure Units: J\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion[:].n_i_volume_average\nVolume averaged density of this ion species (averaged over the plasma volume up to the LCFS)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion[:].t_i_volume_average\nVolume averaged temperature of this ion species (averaged over the plasma volume up to the LCFS)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion_time_slice\nTime slice of the profiles1d array used to define the ion composition of the globalquantities/ion array.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ip\nTotal plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.li_3\nInternal inductance. The li3 definition is used, i.e. li3 = 2/R0/mu0^2/Ip^2 * int(Bp^2 dV).Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.n_e_volume_average\nVolume averaged electron density (average over the plasma volume up to the LCFS)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.polarized_fuel_fraction\nN/AData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.resistive_psi_losses\nResistive part of the poloidal flux losses, defined as the volume-averaged scalar product of the electric field and the ohmic current density, normalized by the plasma current and integrated in time from the beginning of the plasma discharge: int ( (int(Efieldtor.johmtor) dV) / Ip ) dt)Units: Wb\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_e_peaking\nElectron temperature peaking factor, defined as the Te value at the magnetic axis divided by the volume averaged Te (average over the plasma volume up to the LCFS)Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_e_volume_average\nVolume averaged electron temperature (average over the plasma volume up to the LCFS)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_i_average_peaking\nIon temperature (averaged over ion species and states) peaking factor, defined as the Ti value at the magnetic axis divided by the volume averaged Ti (average over the plasma volume up to the LCFS)Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.v_loop\nLCFS loop voltage (positive value drives positive ohmic current that flows anti-clockwise when viewed from above)Units: V\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.z_eff_resistive\nVolume average plasma effective charge, estimated from the flux consumption in the ohmic phaseData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_norm\nNormalized poloidal magnetic fluxData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure\nTotal pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].ion_index\nIndex of the corresponding ion species in the ../../../profiles_1d/ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].t_i_average\nIon temperature (averaged on states and ion species)Units: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].zeff\nEffective chargeData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics valueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path\nFor Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3) Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].value\nValue of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].time_width\nWidth of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"core_sources.source[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].current_parallel\nParallel current drivenUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].electrons.particles\nElectron particle sourceUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].electrons.power\nPower coupled to electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].power\nTotal power coupled to the plasmaUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].torque_tor\nToroidal torqueUnits: kg.m^2.s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].total_ion_particles\nTotal ion particle source (summed over ion species)Units: (ions).s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].total_ion_power\nTotal power coupled to ion species (summed over ion species)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].conductivity_parallel\nParallel conductivity due to this sourceUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_parallelUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy\nSource term for the electron energy equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles\nSource term for electron density equationUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_inside\nElectron source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.power_inside\nPower coupled to electrons inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_norm\nNormalized poloidal magnetic fluxData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy\nSource term for the ion energy transport equation.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].fast_particles_energy\nIncoming energy of the fast ion particles (eg. fusion 3.5MeV alphas or 1MeV nbi)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.diamagnetic\nDiamagnetic componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.parallel\nParallel componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.poloidal\nPoloidal componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.radial\nRadial componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal\nToroidal componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.explicit_part\nExplicit part of the source termUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles\nSource term for ion density equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_inside\nIon source inside the flux surface. Cumulative volume integral of the source term for the ion density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].power_inside\nPower coupled to the ion species inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy\nSource terms for the charge state energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles\nSource term for the charge state density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_inside\nState source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].power_inside\nPower coupled to the state inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].j_parallel\nParallel current density source, average(J.B) / B0, where B0 = coresources/vacuumtoroidal_field/b0 Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].momentum_tor\nSource term for total toroidal momentum equationUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].momentum_tor_j_cross_b_field\nContribution to the toroidal momentum source term (already included in the momentum_tor node) corresponding to the toroidal torques onto the thermal plasma due to Lorentz force associated with radial currents. These currents appear as return-currents (enforcing quasi-neutrality, div(J)=0) balancing radial currents of non-thermal particles, e.g. radial currents of fast and trapped neutral-beam-ions.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].energy\nSource term for the neutral energy transport equation.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].particles\nSource term for neutral density equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].energy\nSource terms for the state energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].particles\nSource term for the state density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].torque_tor_inside\nToroidal torque inside the flux surface. Cumulative volume integral of the source term for the total toroidal momentum equationUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy\nSource term for the total (summed over ion species) energy equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_power_inside\nTotal power coupled to ion species (summed over ion species) inside the flux surface. Cumulative volume integral of the source term for the total ion energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"core_transport.model[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].comment\nAny comment describing the modelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].flux_multiplier\nMultiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].e_field_radial\nRadial component of the electric field (calculated e.g. by a neoclassical model)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.availability\nAvailability fraction of the plantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.construction_start_year\nYear that plant construction beginsUnits: year\nData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.cost\nCost to decomission the plantUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].cost\nCost to decommission the systemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].name\nName of the system to decommissionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].subsystem[:].cost\nCost to decommission the subsystemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].subsystem[:].name\nName of the subsystem to decommissionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.cost\nTotal direct capitalUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].cost\nCost of the systemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].subsystem[:].cost\nCost of the subsystemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].subsystem[:].name\nName of the subsystemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_lifetime\nTotal cost of fusion power plantUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].subsystem[:].name\nName of the subsystemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].subsystem[:].yearly_cost\nCost of the subsystem per yearUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].yearly_cost\nCost of system per yearUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.yearly_cost\nAnual cost to operate the plantUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.inflation_rate\nPredicted average rate of future inflationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.learning.hts.learning_rate\nLearning rate for ReBCO technology productionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.learning.hts.production_increase\nFactor by which production of ReBCO multipliesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.levelized_CoE\nLevelized cost of electiricity (total cost / total electricy generated)Units: $/kWh\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.plant_lifetime\nLifetime of the plantUnits: year\nData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"cryostat.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.dd_version\nVersion of the physics data dictionary of this datasetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.imas_version\nVersion of the IMAS infrastructure used to produce this data entry. Refers to the global IMAS repository which links to versions of every infrastructure toolsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin\nDate and time (UTC) at which the pulse started on the experiment, expressed in a human readable form (ISO 8601) : the format of the string shall be : YYYY-MM-DDTHH:MM:SSZ. Example : 2020-07-24T14:19:00ZData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin_epoch.nanoseconds\nElapsed nanoseconds since the time in seconds indicated aboveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin_epoch.seconds\nElapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_end_epoch.nanoseconds\nElapsed nanoseconds since the time in seconds indicated aboveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_end_epoch.seconds\nElapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.comment_after\nComment made at the end of a simulationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.comment_before\nComment made when launching a simulationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_begin\nStart timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_begun\nActual wall-clock time simulation startedUnits: UTC\nData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_current\nCurrent time of the simulationUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_end\nStop timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_ended\nActual wall-clock time simulation finishedUnits: UTC\nData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_restart\nTime of the last restart done during the simulationUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_step\nTime interval between main steps, e.g. storage step (if relevant and constant)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.workflow\nDescription of the workflow which has been used to produce this data entry (e.g. copy of the Kepler MOML if using Kepler)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.identifier\nPersistent identifier allowing to cite this data in a public and persistent way, should be provided as HTTP URIsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.is_referenced_by\nList of documents (e.g. publications) or datasets making use of this data entry (e.g. PIDs of other datasets using this data entry as input)Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.is_replaced_by\nPersistent identifier referencing the new version of this data (replacing the present version)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.license\nLicense(s) under which the data is made available (license description or, more convenient, publicly accessible URL pointing to the full license text)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.replaces\nPersistent identifier referencing the previous version of this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.rights_holder\nThe organisation owning or managing rights over this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.valid\nDate range during which the data is or was valid. Expressed as YYYY-MM-DD/YYYY-MM-DD, where the former (resp. latter) date is the data at which the data started (resp. ceased) to be valid. If the data is still valid, the slash should still be present, i.e. indicate the validity start date with YYYY-MM-DD/. If the data ceased being valid but there is no information on the validity start date, indicate /YYYY-MM-DD.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.current_halo_pol\nPoloidal halo currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.current_halo_tor\nToroidal halo currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_ohm\nTotal ohmic cumulated energy (integral of the power over the disruption duration)Units: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_ohm_halo\nOhmic cumulated energy (integral of the power over the disruption duration) in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_parallel_halo\nCumulated parallel energy (integral of the heat flux parallel power over the disruption duration) in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_radiated_electrons_impurities\nTotal cumulated energy (integral of the power over the disruption duration) radiated by electrons on impuritiesUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_radiated_electrons_impurities_halo\nCumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_ohm\nTotal ohmic powerUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_ohm_halo\nOhmic power in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_parallel_halo\nPower of the parallel heat flux in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_radiated_electrons_impurities\nTotal power radiated by electrons on impuritiesUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_radiated_electrons_impurities_halo\nPower radiated by electrons on impurities in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.psi_halo_boundary\nPoloidal flux at halo region boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].active_wall_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].active_wall_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].current_halo_pol\nPoloidal halo current crossing through this areaUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].end_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].end_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].start_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].start_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].j_runaways\nRunaways parallel current density = average(j.B) / B0, where B0 = Disruption/VacuumToroidalField/ B0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].power_density_conductive_losses\nPower density of conductive losses to the wall (positive sign for losses)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].power_density_radiative_losses\nPower density of radiative losses (positive sign for losses)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].discrete\nList of indices of grid spaces (refers to ../grid/space) for which the source is discretely distributed. For example consider a source of 3.5 MeV alpha particles provided on a grid with two coordinates (spaces); rho_tor and energy. To specify that the source is given at energies exactly equal to 3.5 MeV, let discret have length 1 and set discrete(1)=2 since energy is dimension number 2. The source is then proportional to delta( 1 - energy / 3.5MeV ), where delta is the direct delta distribution. Discrete dimensions can only be used when the grid is rectangular.Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: (m.s^-1)^-3.m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"distribution_sources.source[:].ggd[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: (m.s^-1)^-3.m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].particles\nParticle source rateUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].power\nTotal power of the sourceUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.particles\nParticle losses due to shinethroughUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.power\nPower losses due to shinethroughUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.torque_tor\nToroidal torque losses due to shinethroughUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].torque_tor\nTotal toroidal torque of the sourceUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"distribution_sources.source[:].markers[:].orbit_integrals.expressions\", \"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].orbit_integrals.n_tor\", \"distribution_sources.source[:].markers[:].orbit_integrals.m_pol\", \"distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions\", \"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_beamlets_group\nIndex of the NBI beamlets group considered. Refers to the \"unit/beamlets_group\" array of the NBI IDS. 0 means sum over all beamlets groups.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_unit\nIndex of the NBI unit considered. Refers to the \"unit\" array of the NBI IDS. 0 means sum over all NBI units.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].energy\nSource term for the energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].momentum_tor\nSource term for the toroidal momentum equationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].particles\nSource term for the density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].temperature\nReference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)Units: eV\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].current_tor\nToroidal current driven by the distributionUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy\nTotal energy in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy_fast\nTotal energy of the fast particles in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy_fast_parallel\nParallel energy of the fast particles in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].particles_fast_n\nNumber of fast particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].particles_n\nNumber of particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].particles\nParticle source rateUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].power\nTotal power of the sourceUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].torque_tor\nTotal toroidal torque of the sourceUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.particles\nSource rate of thermal particles due to the thermalisation of fast particlesUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.power\nPower input to the thermal particle population due to the thermalisation of fast particlesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.torque\nTorque input to the thermal particle population due to the thermalisation of fast particlesUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].is_delta_f\nIf isdeltaf=1, then the distribution represents the deviation from a Maxwellian; isdeltaf=0, then the distribution represents all particles, i.e. the full-f solutionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"distributions.distribution[:].markers[:].orbit_integrals.expressions\", \"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].orbit_integrals.n_tor\", \"distributions.distribution[:].markers[:].orbit_integrals.m_pol\", \"distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"distributions.distribution[:].markers[:].orbit_integrals_instant.expressions\", \"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_beamlets_group\nIndex of the NBI beamlets group considered. Refers to the \"unit/beamlets_group\" array of the NBI IDS. 0 means sum over all beamlets groups.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_unit\nIndex of the NBI unit considered. Refers to the \"unit\" array of the NBI IDS. 0 means sum over all NBI units.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.energy\nEnergy at which the fast and thermal particle populations were separated, as a function of radiusUnits: eV\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.energy\nSource rate of energy density within the thermal particle population due to the thermalisation of fast particlesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.momentum_tor\nSource rate of toroidal angular momentum density within the thermal particle population due to the thermalisation of fast particlesUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.particles\nSource rate of thermal particle density due to the thermalisation of fast particlesUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.rho_tor\nToroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.theta_geometric\nGeometrical poloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.theta_straight\nStraight field line poloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].antenna_name\nName of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].index_in_antenna\nIndex of the wave (starts at 1), separating different waves generated from a single antenna.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"divertors.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].identifier\nAlphanumeric identifier of divertorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].name\nName of the divertorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].particle_flux_recycled_total.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].particle_flux_recycled_total.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].particle_flux_recycled_total.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_black_body.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_black_body.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_black_body.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_conducted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_conducted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_conducted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_convected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_convected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_convected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_currents.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_currents.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_currents.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_incident.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_radiated.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_radiated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_radiated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_recombination_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_plasma.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_recombination_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_plasma.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_thermal_extracted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_thermal_extracted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_thermal_extracted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].extension_r\nTarget length projected on the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].extension_z\nTarget length projected on the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].flux_expansion.data\nDataData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].flux_expansion.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].flux_expansion.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].heat_flux_steady_limit_max\nMaximum steady state heat flux allowed on divertor target surface (engineering design limit)Units: W.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].identifier\nAlphanumeric identifier of targetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].name\nName of the targetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_black_body.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_black_body.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_black_body.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_conducted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_conducted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_conducted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_convected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_convected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_convected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_currents.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_currents.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_currents.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_flux_peak.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_flux_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_flux_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident_fraction.data\nDataData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_incident_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_radiated.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_radiated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_radiated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_recombination_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_plasma.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_recombination_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_plasma.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].t_e_target_sputtering_limit_max\nMaximum plasma temperature allowed on the divertor target to avoid excessive sputteringUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].temperature_limit_max\nMaximum surface target temperature allowed to prevent damage (melting, recrystallization, sublimation, etc...)Units: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].identifier\nAlphanumeric identifier of tileData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].name\nName of the tileData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].shunt_index\nIf the tile carries a measurement shunt, index of that shunt (in the magnetics IDS shunt array)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_area\nArea of the tile surface facing the plasmaUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].surface_outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].surface_outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_pol.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tilt_angle_pol.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_pol.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_tor.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tilt_angle_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].n_e_target\nElectron density at divertor targetUnits: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].sol_heat_decay_length\nHeat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].sol_heat_spreading_length\nHeat flux spreading length in SOL at equatorial mid-plane, this is the S power spreading parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031. Relevant only for attached plasmas.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].t_e_target\nElectron temperature at divertor targetUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].wetted_area.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].wetted_area.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].wetted_area.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].wetted_area.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].wetted_area.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].wetted_area.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].identifier\nBeam identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r_limit_max\nMajor radius upper limit for the systemUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r_limit_min\nMajor radius lower limit for the systemUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].mode\nIdentifier for the main plasma wave mode excited by the EC beam. For the ordinary mode (O-mode), mode=1. For the extraordinary mode (X-mode), mode=-1Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].name\nBeam nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].o_mode_fraction\nFraction of EC beam power launched in ordinary (O) mode. If all power is launched in ordinary mode (O-mode), omodefraction = 1.0. If all power is launched in extraordinary mode (X-mode), omodefraction = 0.0Data Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].phase.angle\nRotation angle for the phase ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].phase.curvature\nInverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)Units: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].spot.angle\nRotation angle for the spot ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].spot.size\nSize of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].steering_angle_pol\nSteering angle of the EC beam in the R,Z plane (from the -R axis towards the -Z axis), anglepol=atan2(-kZ,-kR), where kZ and k_R are the Z and R components of the mean wave vector in the EC beamUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].steering_angle_tor\nSteering angle of the EC beam away from the poloidal plane that is increasing towards the positive phi axis, angletor=arcsin(kphi/k), where k_phi is the component of the wave vector in the phi direction and k is the length of the wave vector. Here the term wave vector refers to the mean wave vector in the EC beamUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].time\nTime base used for launchingposition, omode_fraction, angle, spot and phase quantitiesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ec_launchers.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].beam.phase.angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.curvature.data\nDataUnits: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"ece.channel[:].beam.phase.curvature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.curvature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].beam.spot.angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.size.data\nDataUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"ece.channel[:].beam.spot.size.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.size.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.data\nDataData Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].if_bandwidth\nFull-width of the Intermediate Frequency (IF) bandpass filterUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.data\nDataData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].t_e_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].t_e_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].time\nTimebase for the processed dynamic data of this channel (outside of the beam structure)Units: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ece.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].polarization_angle\nAlignment angle of the polarizer in the (x1,x2) plane. Electric fields parallel to the polarizer angle will be reflected. The angle is defined with respect to the x1 unit vector, positive in the counter-clockwise direction when looking towards the plasmaUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"ece.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"ece.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.rho_tor_norm\nNormalised toroidal flux coordinate of the measurementData Type: FLT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].a_field_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].z_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].j_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].n_i_total_over_n_e[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_thermal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].t_i_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].zeff[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].q\nSafety factorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics valueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path\nFor Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3) Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].value\nValue of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].time_width\nWidth of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].current[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].electrons.energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].electrons.particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].total_ion_energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"edge_transport.model[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].flux_multiplier\nMultiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.active_coils\nList of URIs of the active coils considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_active.coil\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes\nList of URIs of the poloidal field probes considered in the IDSData Type: STR_1D\nCoordinates: [\"magnetics.b_field_pol_probe\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_active\nPoloidal field coupling from active coils to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"magnetics.b_field_pol_probe\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_passive\nPoloidal field coupling from passive loops to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"em_coupling.b_field_pol_probes\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_plasma\nPoloidal field coupling from plasma elements to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"em_coupling.b_field_pol_probes\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"em_coupling.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].columns_uri\nList of URIs corresponding to the columns (2nd dimension) of the coupling matrix. See examples above (rows_uri)Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].data\nCoupling matrixUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"em_coupling.coupling_matrix[:].rows_uri\", \"em_coupling.coupling_matrix[:].columns_uri\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].name\nName of this coupling matrixData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].rows_uri\nList of URIs corresponding to the rows (1st dimension) of the coupling matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector, it is sufficient to give a insgle uri, the one of the vector with the impliicit notation (:), e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.flux_loops\nList of URIs of the flux loops considered in the IDSData Type: STR_1D\nCoordinates: [\"magnetics.flux_loop\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_active_active\nMutual inductance coupling from active coils to active coilsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.active_coils\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_active\nMutual inductance coupling from active coils to flux loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_passive\nMutual inductance coupling from passive loops to flux loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_plasma\nMutual inductance from plasma elements to poloidal flux loops Units: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_passive_active\nMutual inductance coupling from active coils to passive loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.passive_loops\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_passive_passive\nMutual inductance coupling from passive loops to passive loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.passive_loops\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_active\nMutual inductance coupling from active coils to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_passive\nMutual inductance coupling from passive loops to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_plasma\nMutual inductance coupling from plasma elements to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.passive_loops\nList of URIs of the passive loops considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_passive.loop\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.plasma_elements\nList of URIs of the plasma elements considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_plasma.element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"equilibrium.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.active_limiter_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.active_limiter_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.elongation_lower\nElongation (lower half w.r.t. geometric axis) of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.elongation_upper\nElongation (upper half w.r.t. geometric axis) of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.geometric_axis.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.geometric_axis.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.minor_radius\nMinor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].boundary.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.ovality\nOvality of the plasma boundary [MXH c1]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.psi\nValue of the poloidal flux at which the boundary is takenUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.psi_norm\nValue of the normalised poloidal flux at which the boundary is taken (typically 99.x %), the flux being normalised to its value at the separatrixData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness\nSquareness of the plasma boundary [MXH -s2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_lower_inner\nLower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_lower_outer\nLower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_upper_inner\nUpper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_upper_outer\nUpper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.strike_point[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.strike_point[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.tilt\nTilt of the plasma boundary [MXH c0]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity\nTriangularity of the plasma boundary [MXH sin(s1)]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity_lower\nLower triangularity of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity_upper\nUpper triangularity of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.twist\nTwist of the plasma boundary [MXH c2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.type\n0 (limiter) or 1 (diverted)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.x_point[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.x_point[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary_secondary_separatrix.distance_inner_outer\nDistance between the inner and outer separatrices, in the major radius direction, at the plasma outboard and at the height corresponding to the maximum R for the inner separatrix.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.flux_loop[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.ip.chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.ip.measured\nMeasured valueUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.measured\nMeasured valueUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.reconstructed\nValue calculated from the reconstructed equilibriumUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].measured\nMeasured valueUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].measured\nMeasured valueUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].measured\nMeasured valueUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].measured\nMeasured valueUnits: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pf_passive_current[:].measured\nMeasured valueUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pf_passive_current[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].measured\nMeasured valueUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].measured\nMeasured valueUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].measured\nMeasured valueData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_r\nSquared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_z\nSquared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_measured.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_measured.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].chi_squared_r\nSquared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].chi_squared_z\nSquared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_measured.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_measured.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_value\nValue of the residual deviation between the left and right hand side of the Grad Shafranov equation, evaluated as per gradshafranovdeviation_expressionUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].j_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].j_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].phi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: rad\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].theta[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].values\nOne scalar value is provided per element in the grid subset.Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.area\nArea of the LCFS poloidal cross sectionUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_normal\nNormalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA] Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_pol\nPoloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_tor\nToroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.r\nMajor radius of the current center, defined as integral over the poloidal cross section of (j_torrdS) / IpUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.velocity_z\nVertical velocity of the current centerUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.z\nHeight of the current center, defined as integral over the poloidal cross section of (j_torzdS) / IpUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.energy_mhd\nPlasma energy content = 3/2 * int(p,dV) with p being the total pressure (thermal + fast particles) [J]. Time-dependent; ScalarUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.ip\nPlasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.length_pol\nPoloidal length of the magnetic surfaceUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.li_3\nInternal inductanceData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.b_field_tor\nTotal toroidal magnetic field at the magnetic axisUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.r\nMajor radius of the magnetic axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.z\nHeight of the magnetic axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.plasma_inductance\nPlasma inductance 2 Emagnetic/Ip^2, where Emagnetic = 1/2 * int(psi.j_tor.dS) (integral over the plasma poloidal cross-section)Units: H\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.plasma_resistance\nPlasma resistance = int(e_field.j.dV) / Ip^2Units: ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_axis\nPoloidal flux at the magnetic axisUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_boundary\nPoloidal flux at the selected plasma boundary Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_external_average\nAverage (over the plasma poloidal cross section) plasma poloidal magnetic flux produced by all external circuits (CS and PF coils, eddy currents, VS in-vessel coils), given by the following formula : int(psiexternal.jtor.dS) / IpUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_95\nq at the 95% poloidal flux surface (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_axis\nq at the magnetic axisData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.psi\nMinimum q position in poloidal fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.psi_norm\nMinimum q position in normalised poloidal fluxData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.rho_tor_norm\nMinimum q position in normalised toroidal flux coordinateData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.value\nMinimum q valueData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.rho_tor_boundary\nToroidal flux coordinate at the selected plasma boundaryUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.v_external\nExternal voltage, i.e. time derivative of psiexternalaverage (with a minus sign : - dpsiexternalaverage/dtime)Units: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.volume\nTotal plasma volumeUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_average\nFlux surface averaged modulus of B (always positive, irrespective of the sign convention for the B-field direction).Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_max\nMaximum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_min\nMinimum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.beta_pol\nPoloidal beta profile. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.darea_dpsi\nRadial derivative of the cross-sectional area of the flux surface with respect to psiUnits: m^2.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.darea_drho_tor\nRadial derivative of the cross-sectional area of the flux surface with respect to rho_torUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dpressure_dpsi\nDerivative of pressure w.r.t. psiUnits: Pa.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dpsi_drho_tor\nDerivative of Psi with respect to Rho_TorUnits: Wb/m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dvolume_dpsi\nRadial derivative of the volume enclosed in the flux surface with respect to PsiUnits: m^3.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dvolume_drho_tor\nRadial derivative of the volume enclosed in the flux surface with respect to Rho_TorUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.elongation\nElongationData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.f\nDiamagnetic function (F=R B_Phi)Units: T.m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.f_df_dpsi\nDerivative of F w.r.t. Psi, multiplied with FUnits: T^2.m^2/Wb\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.fsa_bp\nFlux surface averaged BpUnits: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.geometric_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.geometric_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm1\nFlux surface averaged 1/R^2Units: m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm10\nFlux surface averaged R^2Units: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm2\nFlux surface averaged |gradrhotor|^2/R^2Units: m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm3\nFlux surface averaged |gradrhotor|^2Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm4\nFlux surface averaged 1/B^2Units: T^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm5\nFlux surface averaged B^2Units: T^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm6\nFlux surface averaged |gradrhotor|^2/B^2Units: T^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm7\nFlux surface averaged |gradrhotor|Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm8\nFlux surface averaged RUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm9\nFlux surface averaged 1/RUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.j_parallel\nFlux surface averaged approximation to parallel current density = average(j.B) / B0, where B0 = /vacuumtoroidalfield/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.j_tor\nFlux surface averaged toroidal current density = average(j_tor/R) / average(1/R)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.mass_density\nMass densityUnits: kg.m^-3\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.phi\nToroidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.psi\nPoloidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.psi_norm\nNormalised poloidal flux coordinateData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.r_inboard\nRadial coordinate (major radius) on the inboard side of the magnetic axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.r_outboard\nRadial coordinate (major radius) on the outboard side of the magnetic axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_tor\nToroidal flux coordinate = sqrt(phi/(pi*b0)), where the toroidal flux, phi, corresponds to timeslice/profiles1d/phi, the toroidal magnetic field, b0, corresponds to vacuumtoroidalfield/b0 and pi can be found in the IMAS constantsUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_volume_norm\nNormalised square root of enclosed volume (radial coordinate). The normalizing value is the enclosed volume at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_lower_inner\nLower inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_lower_outer\nLower outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_upper_inner\nUpper inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_upper_outer\nUpper outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.trapped_fraction\nTrapped particle fractionData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.triangularity_lower\nLower triangularity w.r.t. magnetic axisData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.triangularity_upper\nUpper triangularity w.r.t. magnetic axisData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.volume\nVolume enclosed in the flux surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_r\nR component of the poloidal magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_tor\nToroidal component of the magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_z\nZ component of the poloidal magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].j_parallel\nDefined as (j.B)/B0 where j and B are the current density and magnetic field vectors and B0 is the (signed) vacuum toroidal magnetic field strength at the geometric reference point (R0,Z0). It is formally not the component of the plasma current density parallel to the magnetic fieldUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].j_tor\nToroidal plasma current densityUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].phi\nToroidal fluxUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].psi\nValues of the poloidal flux at the grid in the poloidal planeUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].theta\nValues of the poloidal angle on the gridUnits: rad\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ferritic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].dimension\nSpace dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].dimension\nDimension of the objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.x\nList of X coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.y\nList of Y coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.z\nList of Z coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].ggd_object_index\nIndex of GGD volumic object corresponding to each element. Refers to the array /gridggd/space(1)/objectsper_dimension(4)/objectData Type: INT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].permeability_table_index\nIndex of permeability table to be used for each element. If not allocated or if an element is equal to EMPTYINT, use the sibling saturated relative permeability instead ../relativepermeability, for that elementData Type: INT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].saturated_relative_permeability\nSaturated relative magnetic permeability of each elementUnits: H.m^-1\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_r\nR component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_tor\nToroidal component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_z\nZ component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_r\nR component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_tor\nToroidal component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_z\nZ component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].volume\nVolume of each element of this objectUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].b_field\nArray of magnetic field values, for each of which the relative permeability is givenUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].description\nDescription of this tableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].name\nName of this tableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].relative_permeability\nRelative permeability as a function of the magnetic fieldData Type: FLT_1D\nCoordinates: [\"ferritic.permeability_table[:].b_field\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.data\nDataUnits: T\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"focs.b_field_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"focs.b_field_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"focs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"focs.current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"focs.current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_length\nSpun fibre length on the vacuum vesselUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.beat_length\nLinear beat lengthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.id\nID of the fibre, e.g. commercial referenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.spun\nSpun periodUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.spun_initial_azimuth\nSpun fibre initial azimuthUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.twist\nTwist periodUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.verdet_constant\nVerdet constantUnits: rad.T^-1.m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.id\nID of the FOCSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.name\nName of the FOCSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"focs.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"focs.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s0\nS0 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s1\nS1 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s2\nS2 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s3\nS3 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s0\nS0 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s1\nS1 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s2\nS2 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s3\nS3 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gas_injection.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.pipe[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].identifier\nID of the injection pipeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].length\nPipe lengthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].name\nName of the injection pipeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].valve_indices\nIndices (from the ../../valve array of structure) of the valve(s) that are feeding this pipeData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].electron_rate.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].electron_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].electron_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate_max\nMaximum flow rate of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate_min\nMinimum flow rate of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].identifier\nID of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].name\nName of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].pipe_indices\nIndices (from the ../../pipe array of structure) of the pipe(s) that are fed by this valveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].response_curve.flow_rate\nFlow rate at the exit of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].response_curve.voltage\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].response_curve.voltage\nVoltage applied to open the valveUnits: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gas_pumping.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_pumping.duct[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].identifier\nID of the pumping ductData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].name\nName of the pumping ductData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_pumping.duct[:].species[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].label\nString identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gyrokinetics_local.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.collisions.collisionality_norm\nNormalised collisionality between two speciesData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.b_field_tor_sign\nSign of the toroidal magnetic fieldData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dc_dr_minor_norm\nDerivative of the 'c' shape coefficients with respect to rminornormData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.flux_surface.shape_coefficients_c\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.delongation_dr_minor_norm\nDerivative of the elongation with respect to rminornormData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dgeometric_axis_r_dr_minor\nDerivative of the major radius of the surface geometric axis with respect to r_minorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dgeometric_axis_z_dr_minor\nDerivative of the height of the surface geometric axis with respect to r_minorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.ds_dr_minor_norm\nDerivative of the 's' shape coefficients with respect to rminornormData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.flux_surface.shape_coefficients_s\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.elongation\nElongationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.ip_sign\nSign of the plasma currentData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.magnetic_shear_r_minor\nMagnetic shear, defined as rminornorm/q . dq/drminornorm (different definition from the equilibrium IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.pressure_gradient_norm\nNormalised pressure gradient (derivative with respect to rminornorm)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.q\nSafety factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.r_minor_norm\nNormalised minor radius of the flux surface of interest = 1/2 * (max(R) - min(R))/L_refData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.shape_coefficients_c\n'c' coefficients in the formula defining the shape of the flux surfaceData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.shape_coefficients_s\n's' coefficients in the formula defining the shape of the flux surfaceData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].binormal_wavevector_norm\nNormalised binormal component of the wavevectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\nPoloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_parity\nParity of the perturbed parallel vector potential with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_weight\nAmplitude of the perturbed parallel vector potential normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_parity\nParity of the perturbed parallel magnetic field with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_weight\nAmplitude of the perturbed parallel magnetic field normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_parity\nParity of the perturbed electrostatic potential with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_weight\nAmplitude of the perturbed electrostatic potential normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].frequency_norm\nFrequencyData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_norm\nGrowth rateData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_tolerance\nRelative tolerance on the growth rate (convergence of the simulation)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].initial_value_run\nFlag = 1 if this is an initial value run, 0 for an eigenvalue runData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].poloidal_turns\nNumber of poloidal turns considered in the flux-tube simulationData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\nNormalised time of the gyrokinetic simulationData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].radial_wavevector_norm\nNormalised radial component of the wavevectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.adiabatic_electrons\nFlag = 1 if electrons are adiabatic, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_energy_conservation\nFlag = 1 if the collision operator conserves energy, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_finite_larmor_radius\nFlag = 1 if finite larmor radius effects are retained in the collision operator, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_momentum_conservation\nFlag = 1 if the collision operator conserves momentum, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_pitch_only\nFlag = 1 if only pitch-angle scattering is retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_a_field_parallel\nFlag = 1 if fluctuations of the parallel vector potential are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_b_field_parallel\nFlag = 1 if fluctuations of the parallel magnetic field are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_centrifugal_effects\nFlag = 1 if centrifugal effects are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_coriolis_drift\nFlag = 1 if Coriolis drift is included, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_full_curvature_drift\nFlag = 1 if all contributions to the curvature drift are included (including betaprime), 0 otherwise. Neglecting the betaprime contribution (Flag=0) is only recommended together with the neglect of parallel magnetic field fluctuationsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.angle_pol\nPoloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.binormal_wavevector_norm\nArray of normalised binormal wavevectorsData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.quasi_linear\nFlag = 1 if the non-linear fluxes are in fact calculated by a quasi-linear model, 0 if non-linearData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.radial_wavevector_norm\nArray of normalised radial wavevectorsData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.time_interval_norm\nNormalised time interval used to average fluxes in non-linear runsData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.time_norm\nNormalised time of the gyrokinetic simulationData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.b_field_tor\nToroidal magnetic field at major radius rUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.n_e\nElectron density at outboard equatorial midplane of the flux surface (angle_pol = 0)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.r\nMajor radius of the flux surface of interest, defined as (min(R)+max(R))/2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.t_e\nElectron temperature at outboard equatorial midplane of the flux surface (angle_pol = 0)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].charge_norm\nNormalised chargeData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].density_log_gradient_norm\nNormalised logarithmic gradient (with respect to rminornorm) of the densityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].density_norm\nNormalised densityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].mass_norm\nNormalised massData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].potential_energy_gradient_norm\nEffective potential energy determining the poloidal variation of the species background densityData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species_all.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].potential_energy_norm\nNormalised gradient (with respect to rminornorm) of the effective potential energyData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species_all.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].temperature_log_gradient_norm\nNormalised logarithmic gradient (with respect to rminornorm) of the temperatureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].temperature_norm\nNormalised temperatureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].velocity_tor_gradient_norm\nNormalised gradient (with respect to rminornorm) of the toroidal velocityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.angle_pol\nPoloidal angle grid, from -pi to pi, on which the species dependent effective potential energy (which determines the poloidal variation of the density) is expressed. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.beta_reference\nReference plasma beta (see detailed documentation at the root of the IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.debye_length_norm\nDebye length computed from the reference quantities (see detailed documentation at the root of the IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.shearing_rate_norm\nNormalised ExB shearing rate (for non-linear runs only)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.velocity_tor_norm\nNormalised toroidal velocity of species (all species are assumed to have a purely toroidal velocity with a common toroidal angular frequency)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.data\nDataUnits: (photons).s^-1.m^-2.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"hard_x_rays.channel[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"hard_x_rays.channel[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"hard_x_rays.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].emissivity\nRadial profile of the plasma emissivity in this energy bandUnits: (photons).m^-3.str^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].rho_tor_norm\", \"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].half_width_external\nExternal (towards separatrix) half width of the emissivity peak (in normalised toroidal flux)Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].half_width_internal\nInternal (towards magnetic axis) half width of the emissivity peak (in normalised toroidal flux)Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].peak_position\nNormalised toroidal flux coordinate position at which the emissivity peaksData Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].rho_tor_norm\nNormalised toroidal flux coordinate gridData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].validity_timed\nIndicator of the validity of the emissivity profile data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.coupling\nCoupling efficiency of launched microwave power to the plasmaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].identifier\nIdentifier of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].coupling_resistance.data\nDataUnits: ohm\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].coupling_resistance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].coupling_resistance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].amplitude.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].current[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].current[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].capacitance.data\nDataUnits: F\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].matching_element[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].name\nName of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_forward.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].phase_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_reflected.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].phase_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].amplitude.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].pressure[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].identifier\nIdentifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].pressure[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].distance_to_conductor\nDistance to conducting wall or other conductor behind the antenna strapUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].width_tor\nWidth of strap in the toroidal directionUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].voltage[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].identifier\nIdentifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].voltage[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].name\nName of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].m_pol\nPoloidal mode numbers, used to describe the spectrum of the antenna current. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/zData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].n_tor\nToroidal mode numbers, used to describe the spectrum of the antenna current. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].spectrum\nSpectrum of the total surface current on the antenna strap and passive components expressed in poloidal and toroidal modesUnits: A\nData Type: FLT_2D\nCoordinates: [\"ic_antennas.antenna[:].surface_current[:].m_pol\", \"ic_antennas.antenna[:].surface_current[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ic_antennas.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.reference_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.reference_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\", \"interferometer.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].path_length_variation.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].path_length_variation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].path_length_variation.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].fringe_jump_correction\nSigned number of 2pi phase corrections applied to remove a fringe jump, for each time slice on which a correction has been made Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].wavelength[:].fringe_jump_correction_times\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].fringe_jump_correction_times\nList of time slices of the pulse on which a fringe jump correction has been made Units: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_corrected.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].wavelength[:].phase_corrected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_corrected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_to_n_e_line\nConversion factor to be used to convert phase into line density for this wavelengthUnits: m^-2.rad^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].value\nWavelength valueUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"interferometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.data\nDataData Type: FLT_1D\nCoordinates: [\"interferometer.electrons_n.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.electrons_n.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"interferometer.n_e_volume_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.n_e_volume_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"iron_core.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].b_field\nArray of magnetic field values, for each of which the relative permeability is givenUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].identifier\nID of the segmentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_r.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].magnetisation_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_z.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].magnetisation_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].name\nName of the segmentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].permeability_relative\nRelative permeability of the iron segmentData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].b_field\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"langmuir_probes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].b_field_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].b_field_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel_sigma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].multi_temperature_fits[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].multi_temperature_fits[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area\nArea of the probe surface exposed to the plasma (use when assuming constant effective collection area)Units: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.name\nIDS nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.occurrence\nIDS occurrenceData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity\nIndicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity_timed\nIndicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.validity\nIndicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.validity_timed\nIndicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].time\nTime of maximum penetration of the probe during a given plungeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\nTime vector for describing the dynamics within the plungeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].surface_area\nArea of the surface exposed to the plasma of each collector (constant assuming negligible dependence on e.g. the magnetic field line angle)Units: m^2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].collector\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].distance_to_antenna\nRadial distance to the antenna mouth (grid for the electron density profile). 0 at antenna mouth, increasing towards the plasmaUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.coupling\nCoupling efficiency of launched microwave power to the plasmaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].frequency\nFrequencyUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].identifier\nIdentifier of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].model_name\nName of the antenna model used for antenna spectrum computationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].identifier\nIdentifier of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].name\nName of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].reflection_coefficient.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].reflection_coefficient.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].reflection_coefficient.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"lh_antennas.antenna[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_parallel_peak.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].n_parallel_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_parallel_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].name\nName of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].phase_average.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].phase_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].phase_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.definition\nDefinition of the reference pointData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.phi.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.phi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.phi.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.r.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.z.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].pressure_tank.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].pressure_tank.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].pressure_tank.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].reflection_coefficient.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].reflection_coefficient.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].reflection_coefficient.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].n_pol\nRefraction index in the poloidal direction. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/zData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].n_tor\nRefraction index in the toroidal directionData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].name\nName of the rowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].power_density_spectrum_1d\n1D power density spectrum dP/dn_tor, as a function of timeUnits: W\nData Type: FLT_2D\nCoordinates: [\"lh_antennas.antenna[:].row[:].n_tor\", \"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].power_density_spectrum_2d\n2D power density spectrum d2P/(dntor.dnpol), as a function of timeUnits: W\nData Type: FLT_3D\nCoordinates: [\"lh_antennas.antenna[:].row[:].n_tor\", \"lh_antennas.antenna[:].row[:].n_pol\", \"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"lh_antennas.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.reference_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.reference_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].area\nArea of each turn of the sensor; becomes effective area when multiplied by the turnsUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].bandwidth_3db\n3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].indices_differential\nIndices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].length\nLength of the sensor along it's normal vector (n)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear\nArray of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linearUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].non_linear_response.b_field_non_linear\nMagnetic field value taking into account the non-linear response of the probeUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].poloidal_angle\nAngle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].toroidal_angle\nAngle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].turns\nTurns in the coil, including signData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].area\nArea of each turn of the sensor; becomes effective area when multiplied by the turnsUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].bandwidth_3db\n3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].indices_differential\nIndices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].length\nLength of the sensor along it's normal vector (n)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear\nArray of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linearUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].non_linear_response.b_field_non_linear\nMagnetic field value taking into account the non-linear response of the probeUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].poloidal_angle\nAngle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].toroidal_angle\nAngle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].turns\nTurns in the coil, including signData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"magnetics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].data\nDataUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"magnetics.diamagnetic_flux[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].method_name\nName of the calculation methodData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].area\nEffective area (ratio between flux and average magnetic field over the loop)Units: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.data\nDataUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"magnetics.flux_loop[:].flux.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.flux_loop[:].flux.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].gm9\nIntegral of 1/R over the loop area (ratio between flux and magnetic rigidity R0.B0). Use only if ../type/index = 3 to 6, leave empty otherwise.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].identifier\nID of the flux loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].indices_differential\nIndices (from the flux_loop array of structure) of the two flux loops used to build the flux difference flux(second index) - flux(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].name\nName of the flux loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.flux_loop[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.flux_loop[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"magnetics.ip[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].method_name\nName of the calculation methodData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].area\nEffective area of the loop wrapped around the guiding centre. In case of multiple layers, sum of the areas of each layerUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"magnetics.rogowski_coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.rogowski_coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].identifier\nID of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].indices_compound\nIndices (from the rogowskicoil array of structure) of the partial Rogoswkis used to build the coumpound signal (sum of the partial Rogoswki signals). Can be set to any unique integer value for each section of a compound rogowski coil. Use only if ../measurequantity/index = 5, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].turns_per_metre\nNumber of turns per unit length. In case of multiple layers, turns are counted for a single layerUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].divertor_index\nIf the shunt is located on a given divertor, index of that divertor in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].identifier\nAlphanumeric identifier of the shuntData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].name\nName of the shuntData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].resistance\nShunt resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].target_index\nIf the shunt is located on a divertor target, index of that target in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].tile_index\nIf the shunt is located on a divertor tile, index of that tile in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.shunt[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.shunt[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mhd.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].electrons.temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_tor_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].mass_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].n_i_total[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].t_i_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1.T^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_parallel_over_b_field[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1.T^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].vorticity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].vorticity_over_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].zeff[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mhd_linear.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.fluids_n\nNumber of fluids considered in the modelData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ideal_flag\n1 if ideal MHD is used to populate this IDS, 0 for non-ideal MHDData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].amplitude_multiplier\nMultiplier that is needed to convert the linear mode structures to the amplitude of a non-linearly saturated mode in physical units. If empty, it means that the structures contains no information about non-linearly saturated modeUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].energy_perturbed\nPerturbed energy associated to the modeUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].growthrate\nLinear growthrate of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].m_pol_dominant\nDominant poloidal mode number defining the mode rational surface; for TAEs the lower of the two main m's has to be specifiedData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].n_tor\nToroidal mode number of the MHD modeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].phase\nAdditional phase offset of modeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].imaginary\nImaginary part of the frequency, for a given radial position and every root found at this positionUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real\nReal part of the frequency, for a given radial position and every root found at this positionUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.imaginary\nImaginary partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.real\nReal partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.imaginary\nImaginary partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.real\nReal partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: kg.m^-3\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: kg.m^-3\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.imaginary\nImaginary partUnits: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.real\nReal partUnits: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.imaginary\nImaginary partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.real\nReal partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: Pa\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: Pa\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.imaginary\nImaginary partUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.real\nReal partUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.imaginary\nImaginary partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.real\nReal partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_alfven\nAlven time=R/vA=R0 sqrt(mi ni(rho))/B0Units: s\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_resistive\nResistive time = mu0 rho*rho/1.22/etaneoUnits: s\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: eV\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: eV\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.imaginary\nImaginary partUnits: eV\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.real\nReal partUnits: eV\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].radial_mode_number\nRadial mode numberData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].geometric_coefficients\nSet of 9 geometric coefficients providing the MSE polarisation angle as a function of the local electric and magnetic field components (these are related to the angle between beam and line of sight). The list is ordered as follows : coefficients of BZ, BR, Bphi, ER (numerator of the MSE angle expression); coefficients of BZ, BR, Bphi, ER, EZ (denominator)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...9\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].polarisation_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"mse.channel[:].polarisation_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mse.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_current_fraction.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"nbi.unit[:].beam_current_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_current_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_power_fraction.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"nbi.unit[:].beam_power_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_power_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].angle\nAngle of inclination between a beamlet at the centre of the injection unit surface and the horiontal planeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.angles\nAngle of inclination between a line at the centre of a beamlet and the horizontal plane, for each beamletUnits: rad\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.power_fractions\nFraction of power of a unit injected by each beamletData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.tangency_radii\nTangency radius (major radius where the central line of a beamlet is tangent to a circle around the torus), for each beamletUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].direction\nDirection of the beam seen from above the torus: -1 = clockwise; 1 = counter clockwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].horizontal\nThe horiztonal beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].particles_fraction\nFraction of injected particles in the componentData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].vertical\nThe vertical beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.focal_length_horizontal\nHorizontal focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum horizontal widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.focal_length_vertical\nVertical focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum vertical widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.width_min_horizontal\nThe horizontal width (Full Width at Half Maximum) of the beamlets group at the horizontal focal pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.width_min_vertical\nThe vertical width (Full Width at Half Maximum) of the beamlets group at the vertical focal pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tangency_radius\nTangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_angle\nVariation of the angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal planeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_tangency_radius\nVariation of the tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].width_horizontal\nHorizontal width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid) Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].width_vertical\nVertical width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].efficiency.conversion\nConversion efficiency of electric power to neutral beam powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].efficiency.transmission\nTransmission efficiency of neutral beam from source to portData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].energy.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].energy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].energy.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].identifier\nID of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].name\nName of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].source.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.bias\nADC signal biasUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.discriminator_level_lower\nLower level discriminator of ADCData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.discriminator_level_upper\nUpper level discriminator of ADCData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.impedance\nADC impedanceUnits: ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.input_range\nADC input rangeUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.sampling_rate\nNumber of samples recorded per secondData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].b_field_sensor.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].b_field_sensor.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.x\nComponents along X axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.y\nComponent along Y axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.z\nComponent along Z axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.solid_angle\nAverage solid angle that the detector covers within the voxelUnits: sr\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values\nArray of values for the eventUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values\nArray of values for the eventUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.neutron_flux\nGrouped neutron flux in the detector from one neutron energy bin emitted by the current plasma voxel towards the detectorUnits: m^-2.neutron^-1\nData Type: FLT_5D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\", \"neutron_diagnostic.detector[:].green_functions.source_neutron_energies\", \"neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.neutron_flux_integrated_flags\nArray of flags telling, for each coordinate of the neutronflux, whether the neutronflux has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1Data Type: INT_1D\nCoordinates: [\"1...5\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.response_function\nNumber of events occurring in the detector from one neutron energy bin emitted by the current plasma voxel towards the detectorUnits: events.neutron^-1\nData Type: FLT_5D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\", \"neutron_diagnostic.detector[:].green_functions.source_neutron_energies\", \"neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.response_function_integrated_flags\nArray of flags telling, for each coordinate of the responsefunction, whether the responsefunction has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1Data Type: INT_1D\nCoordinates: [\"1...5\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.source_neutron_energies\nArray of source neutron energy binsUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].count_limit_max\nMaximum count limit under which the detector response is linearUnits: counts.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].count_limit_min\nMinimum count limit above which the detector response is linearUnits: counts.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].counting.data\nDataUnits: counts.s^-1\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].mode[:].counting.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].counting.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].spectrum.data\nDataUnits: counts.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"neutron_diagnostic.detector[:].mode[:].spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].name\nName of the detectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].nuclei_n\nNumber of target nuclei in the dectectorData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature\nTemperature of the detectorUnits: K\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].temperature_sensor.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].temperature_sensor.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].test_generator.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].test_generator.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.fusion_power\nFusion power reconstructed from the detectors signalsUnits: W\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.neutron_flux_total\nTotal Neutron Flux reconstructed from the detectors signalsUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.first_wall.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.first_wall.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.flux_r\nAverage radial component of the neutron fluxUnits: W/m^2\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.flux_z\nAverage vertical component of the neutron fluxUnits: W/m^2\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.power\nLocal neutron power (ie. integrated neutron flux)Units: W\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ntms.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].calculation_method\nDescription of how the mode evolution is calculatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].delta_diff\nExtra diffusion coefficient for the transport equations of Te, ne, Ti Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].deltaw[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].deltaw[:].value\nValue of the contributionUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.calculation_method\nDescription of how the mode evolution is calculatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.delta_diff\nExtra diffusion coefficient for the transport equations of Te, ne, Ti Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].value\nValue of the contributionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dfrequency_dt\nTime derivative of the frequency of the modeUnits: s^-2\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dphase_dt\nTime derivative of the phase of the modeUnits: rad/s\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dwidth_dt\nTime derivative of the full width of the modeUnits: m/s\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.phase\nPhase of the modeUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.rho_tor\nFlux coordinate on which the mode is centredUnits: m\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.rho_tor_norm\nNormalised flux coordinate on which the mode is centredData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\nTime array used to describe the detailed evolution of the NTMUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.torque[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.torque[:].value\nValue of the contributionUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.width\nFull width of the modeUnits: m\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dfrequency_dt\nTime derivative of the frequency of the modeUnits: s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dphase_dt\nTime derivative of the phase of the modeUnits: rad/s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dwidth_dt\nTime derivative of the full width of the modeUnits: m/s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.cause\nCause of the mode onsetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.phase\nPhase of the mode at onsetUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.time_offset\nOffset time (when a mode disappears). If the mode reappears later in the simulation, use another index of the mode array of structureUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.time_onset\nOnset timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.width\nSeed island full width at onset timeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].phase\nPhase of the modeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].rho_tor\nFlux coordinate on which the mode is centredUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].rho_tor_norm\nNormalised flux coordinate on which the mode is centredData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].torque[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].torque[:].value\nValue of the contributionUnits: kg.m^2.s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].width\nFull width of the modeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"ntms.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"operational_instrumentation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].acceleration.data\nDataUnits: m.s^-2\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].acceleration.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].acceleration.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_uris\nIMAS URI of the system(s) to which this sensor is attached. Two for displacement sensors, one for the other types of sensorsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].gauge_length\nLength of the strain gaugeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].identifier\nID of the sensorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].length.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].length.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].length.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].name\nName of the sensorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain.data\nDataData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].strain.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain_rosette.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"operational_instrumentation.sensor[:].strain_rosette.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain_rosette.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].temperature.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].temperature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].temperature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pellets.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].name\nName of the launcher (unique within the set of all launchers of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.size\nSize of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the lengthData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].frequency\nFrequency of pellets launchedUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].density\nMaterial density of the species in the pelletUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].fraction\nAtomic fraction of the species in the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].sublimation_energy\nSublimation energy per atomUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].thickness\nLayer thicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.ablated_particles\nNumber of ablated particles (electrons) along the pellet path Data Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.ablation_rate\nAblation rate (electrons) along the pellet path Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.distance\nDistance along the pellet path, with the origin taken at pathgeometry/firstpoint. Used as the main coordinate for the path_profiles structure Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.n_e\nElectron density along the pellet path Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.position.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.position.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.psi\nPoloidal flux along the pellet path Units: Wb\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm\nNormalised toroidal coordinate along the pellet path Data Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm_drift\nDifference to due ExB drifts between the ablation and the final deposition locations, in terms of the normalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.t_e\nElectron temperature along the pellet path Units: eV\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.velocity\nPellet velocity along the pellet path Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.label\nString identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.molecules_n\nNumber of molecules of the propellant gas injected in the vacuum vessel when launching the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.size\nSize of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the lengthUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].density\nMaterial density of the species in the pelletUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].fraction\nAtomic fraction of the species in the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].sublimation_energy\nSublimation energy per atomUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].velocity_initial\nInitial velocity of the pellet as it enters the vaccum chamberUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].connections\nDescription of the supplies and coils connections (nodes) across the circuit. Nodes of the circuit are listed as the first dimension of the matrix. Supplies (listed first) and coils (listed second) SIDES are listed as the second dimension. Thus the second dimension has a size equal to 2*(Nsupplies+Ncoils). Nsupplies (resp. Ncoils) is the total number of supplies (resp. coils) listed in the supply (resp.coil) array of structure, i.e. including also supplies/coils that are not part of the actual circuit. The (i,j) matrix elements are 1 if the j-th supply or coil side is connected to the i-th node, or 0 otherwise. For coils, sides are listed so that a current flowing from side 1 to side 2 (inside the coil) is positive (i.e. counter-clockwise when seen from above).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.circuit[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].identifier\nID of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].name\nName of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].type\nType of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.circuit[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max\nList of values of the maximum magnetic field on the conductor surface (coordinate for currentlimitmax)Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max_timed.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].b_field_max_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current_limit_max\nMaximum tolerable current in the conductorUnits: A\nData Type: FLT_2D\nCoordinates: [\"pf_active.coil[:].b_field_max\", \"pf_active.coil[:].temperature\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].area\nCross-sectional areas of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].identifier\nIdentifier of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].name\nName of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].turns_with_sign\nNumber of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].energy_limit_max\nMaximum Energy to be dissipated in the coilUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_radial.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial_crushing.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_radial_crushing.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial_crushing.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_vertical.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical_crushing.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_vertical_crushing.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical_crushing.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].identifier\nAlphanumeric identifier of coils used for convenienceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance_additional.data\nDataUnits: Ohm\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].resistance_additional.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance_additional.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].temperature\nList of values of the conductor temperature (coordinate for currentlimitmax)Units: K\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.combination_matrix\nForce limits are expressed as a linear combination of the forces on each individual coil. The weights of the linear combination are given by this matrix, while the limits are given by the sibling nodes limitmin and limitmax. Each row of this matrix corresponds to a force limit. The columns represent, for each coil, the 4 types of forces on the coil namely [coil1radial, coil1vertical, coil1radialcrush, coil1verticalcrush, coil2radial, coil2vertical, coil2radialcrush, coil2verticalcrush, ...]. There are therefore 4*coils_n columns.Data Type: FLT_2D\nCoordinates: [\"pf_active.force_limits.limit_max\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.force.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.force_limits.force.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.force.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.limit_max\nMaximum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unboundedUnits: N\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.limit_min\nMinimum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unboundedUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.force_limits.limit_max\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.supply[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limit_max\nMaximum current in the supplyUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limit_min\nMinimum current in the supplyUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limiter_gain\nGain to prevent overcurrent in a linear model of the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].delay\nPure delay in the supplyUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].energy_limit_max\nMaximum energy to be dissipated in the supply during a pulseUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].filter_denominator\nCoefficients of the denominator, in increasing order : b0 + b1s + ... + bms^m; used for a linear supply descriptionUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].filter_numerator\nCoefficients of the numerator, in increasing order : a0 + a1s + ... + ans^n; used for a linear supply descriptionUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].identifier\nIdentifier of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].name\nName of the PF supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].nonlinear_model\nDescription of the nonlinear transfer function of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].resistance\nPower supply internal resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].type\nType of the supply; TBD add free description of non-linear power suppliesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.supply[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage_limit_max\nMaximum voltage from the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage_limit_min\nMinimum voltage from the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_passive.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].current\nPassive loop currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].area\nCross-sectional areas of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].identifier\nIdentifier of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].name\nName of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].turns_with_sign\nNumber of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].name\nName of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].resistance\nPassive loop resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].resistivity\nPassive loop resistivityUnits: Ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].time\nTimebase for the dynamic nodes of this loop located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].area\nCross-sectional area of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].current\nCurrent in the plasma elementUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].time\nTimebase for the dynamic nodes located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].e_field_parallel\nParallel electric field along each field lineUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].e_field_townsend\nTownsend electric field along each field lineUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.b_field_lines[:].grid.dim1\", \"plasma_initiation.b_field_lines[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].lengths\nLength of each field lineUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].open_fraction\nFraction of open field lines : ratio open fields lines / (open+closed field lines)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].pressure\nPrefill gas pressure used in Townsend E field calculationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].starting_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].starting_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"plasma_initiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_perpendicular.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.b_field_perpendicular.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_perpendicular.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_stray.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.b_field_stray.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_stray.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.connection_length.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.connection_length.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.connection_length.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.coulomb_logarithm.data\nDataData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.coulomb_logarithm.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.coulomb_logarithm.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].e_field_tor\nToroidal component of the electric fieldUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.profiles_2d[:].grid.dim1\", \"plasma_initiation.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.profiles_2d[:].grid.dim1\", \"plasma_initiation.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.data\nDataData Type: FLT_1D\nCoordinates: [\"polarimeter.channel[:].ellipticity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"polarimeter.channel[:].ellipticity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity_initial\nInitial ellipticity before entering the plasmaUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"polarimeter.channel[:].faraday_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"polarimeter.channel[:].faraday_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].polarisation_initial\nInitial polarisation vector before entering the plasmaUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].wavelength\nWavelength used for polarimetryUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"polarimeter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pulse_schedule.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].z_ion\nIon chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_greenwald_fraction.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_pedestal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_pedestal_greenwald_fraction.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].identifier\nIdentifier of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].name\nName of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_pedestal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].identifier\nIdentifier of the beamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].name\nName of the beamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].duration\nDuration of this eventUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].identifier\nUnique identifier of this event provided by the scheduling / event handlerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].listeners\nSystems listening to this eventData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].provider\nSystem having generated this eventData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].time_stamp\nTime stamp of this eventUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].identifier\nIdentifier of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].name\nName of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].identifier\nIdentifier of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].name\nName of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].identifier\nIdentifier of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].name\nName of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].identifier\nIdentifier of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].identifier\nIdentifier of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].name\nName of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].angle\nAngle between the direction in which the gap is measured (in the poloidal cross-section) and the horizontal axis. Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].identifier\nIdentifier of the gapData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].name\nName of the gapData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].r\nMajor radius of the reference pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].z\nHeight of the reference pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.ovality.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.tilt.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.twist.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.dpressure_dpsi.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: Pa.Wb^-1\nData Type: FLT_2D\nCoordinates: [\"pulse_schedule.profiles_control.psi_norm\", \"pulse_schedule.profiles_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.f_df_dpsi.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"pulse_schedule.profiles_control.psi_norm\", \"pulse_schedule.profiles_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.psi_norm\nRadial dimensionData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum.reference\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"radiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].electrons.emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].ion[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].neutral[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power\nTotal power emitted by all speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_electrons\nPower emitted by electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_ion_total\nTotal power emitted by all ion speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_neutral_total\nTotal power emitted by all neutral speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power\nTotal power emitted by all speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_electrons\nPower emitted by electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_ion_total\nTotal power emitted by all ion speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_neutral_total\nTotal power emitted by all neutral speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].electrons.emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].electrons.power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].emissivity_ion_total\nEmissivity (summed over ion species)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].emissivity_neutral_total\nEmissivity (summed over neutral species)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].power_inside_ion_total\nTotal power from ion species (summed over ion species) inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].power_inside_neutral_total\nTotal power from ion species (summed over neutral species) inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"radiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"real_time_data.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].name\nTopic nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].sample\nIndex of sample (time stamp counter)Data Type: INT_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].allocated_position\nAllocation of signal to a position in the SDN (1..N), or several positions in case of signal reshaping; this will be implementation specificData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].data_str\nSignal data (e.g. diagnostic signal or PCS command), serialized as a stringData Type: STR_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].data_type\nSignal data typeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].name\nSignal nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].quality\nIndicator of the quality of the signal. Following ITER PCS documentation (https://user.iter.org/?uid=354SJ3&action=get_document), possible values are: 1 - GOOD (the nominal state); 2 - INVALID (data no usable); 3 - DATA INTEGRITY ERROR (e.g. out of bounds with respect to expectations, calibration error,...)Data Type: INT_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].time_stamp\nTime of creation for all signals belonging to this topic. A set of time stamps can be recorded if neededUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].amplitude.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.e_field_radial\nRadial electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.radial_width\nWidth in the radial direction over which fluctuating profiles are processedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.shift\nDoppler frequency shift (for the main peak of the power spectrum)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.time_width\nWidth of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.wavenumber\nWavenumber probed by the diagnosticUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.dn_e_over_n_e\nRelative amplitude of the density fluctuations post-processed for swept and fixed frequency (profile/one point)Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.radial_width\nWidth in the radial direction over which fluctuating profiles are processedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.time_width\nWidth of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier\nArray of frequencies used for the Fourier transformUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.power_log\nPower spectrum in log scaleUnits: dB\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier\", \"reflectometer_fluctuation.channel[:].fluctuations_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.time_width\nWidth of the time interval over which the spectrum is processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].frequencies.data\nDataUnits: Hz\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].frequencies.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].frequencies.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].phase.data\nDataUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.i_component\nI component of the IQ detector used to retrieve the phase of signal's envelopeUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].raw_signal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.q_component\nQ component of the IQ detector used to retrieve the phase of signal's envelopeUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].raw_signal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].sweep_time\nDuration of a sweepUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"reflectometer_fluctuation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.type\nType of reflectometer (frequency_swept, radar, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].amplitude.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.channel[:].antenna_detection.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.channel[:].antenna_emission.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].cut_off_frequency\nCut-off frequency as a function of measurement position and timeUnits: Hz\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].frequencies\nArray of frequencies scanned during a sweepUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].phase.data\nDataUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].sweep_time\nDuration of a sweepUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"reflectometer_profile.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.type\nType of reflectometer (frequency_swept, radar, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].frequency_main\nMain frequency used to probe the plasma (before upshifting and modulating)Units: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].i_component\nI component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vectorUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].bandwidth[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase\nPhase of the envelope of the probing signal, relative to the phase at launchUnits: rad\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase_quadrature.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].phase_quadrature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase_quadrature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].q_component\nQ component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vectorUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].time\nTimebase for this bandwidthUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].time_detector\nHigh sampling timebase of the IQ-detector signal measurementsUnits: s\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.parameters\nValues of the formula's parameters alpha1, ..., alphaNUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"refractometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.type\nType of refractometer (differential, impulse, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.Psol_R\nPsol / RUnits: W/m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.beta_normal\nNormalized total plasma beta (MHD)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.coil_j_margin\nMagnet coil Jcrit / JmaxData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.coil_stress_margin\nMagnet coil yieldstress / maxstressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.cost\nTotal FPP costUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.flattop_duration\nDuration of the flattop (use Inf for steady-state)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.h98y2\nH98y2 ITER elmy H-mode confinement scaling factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.hds03\nPetty 2003 H-mode thermal energy confinement scaling factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.lh_power_threshold_fraction\nFraction of the LH power thresholdData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.ne_peaking\nOn-axis electron density / volume-averaged electron denstiyData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.power_electric_net\nNet electric power generated by the fusion power plantUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.q95\nEdge safety factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.q_pol_omp\nPoloidal heat flux at the outer midplaneUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.tritium_breeding_ratio\nTritium breeding ratio of the whole plantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].temperature\nReference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)Units: eV\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"runaway_electrons.distribution.markers[:].orbit_integrals.expressions\", \"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].orbit_integrals.n_tor\", \"runaway_electrons.distribution.markers[:].orbit_integrals.m_pol\", \"runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions\", \"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].current_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].e_field_critical[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].pitch_angle[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.current_tor\nTotal runaway current (toroidal component)Units: A\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.energy_kinetic\nTotal runaway kinetic energyUnits: J\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.current_density\nRunaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_compton\nCompton source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_dreicer\nDreicer source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_hot_tail\nHot tail source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_total\nTotal source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_tritium\nTritium source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.density\nRunaway electrons densityUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.e_field_critical\nCritical electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.e_field_dreicer\nDreicer electric field (parallel to magnetic field)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.energy_density_kinetic\nRunaways kinetic mean energy densityUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.momentum_critical_avalanche\nCritical momentum for avalanche, Compton and tritiumUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.momentum_critical_hot_tail\nCritical momentum for hot tailUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.pitch_angle\nAverage pitch angle of the runaways distribution function (v_parallel/|v|)Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].current_density\nRunaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_compton\nCompton source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_dreicer\nDreicer source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_hot_tail\nHot tail source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_total\nTotal source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_tritium\nTritium source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].density\nRunaway electrons densityUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].e_field_critical\nCritical electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].e_field_dreicer\nDreicer electric field (parallel to B)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].energy_density_kinetic\nRunaways kinetic mean energy densityUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].momentum_critical_avalanche\nCritical momentum for avalanche, Compton and tritiumUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].momentum_critical_hot_tail\nCritical momentum for hot tailUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].pitch_angle\nAverage pitch angle of the runaways distribution function (v_parallel/|v|)Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.crash_trigger\nFlag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N as follows. 1: crash triggered by the ideal kink criterion; 2: crash triggered by the ideal kink criterion including kinetic effects from fast particles; 31: crash triggered by the resistive kink criterion (meeting necessary conditions for reconnection); 32: crash triggered by the resistive kink criterion (resistive kink mode is unstable). The distinction between 31 and 32 only indicates whether (31) or (32) was the last criterion to be satisfiedData Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.magnetic_shear_q1\nMagnetic shear at surface q = 1, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_crash_time\nTime at which the previous sawtooth crash occuredUnits: s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_crash_trigger\nPrevious crash trigger. Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition NData Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_period\nPrevious sawtooth periodUnits: s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_inversion\nNormalised toroidal flux coordinate at inversion radiusData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_mixing\nNormalised toroidal flux coordinate at mixing radiusData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_q1\nNormalised toroidal flux coordinate at surface q = 1Data Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].e_field_parallel\nParallel electric field = average(E.B) / B0, where CoreProfiles/VacuumToroidal_Field/ B0Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons Units: kg.m/s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_e\nElectron density (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_e_fast\nDensity of fast (non-thermal) electronsUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e\nElectron pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e_fast_parallel\nFast (non-thermal) electron parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e_fast_perpendicular\nFast (non-thermal) electron perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total\nTotal ion pressure (sum over the ion species)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total_fast_parallel\nFast (non-thermal) total ion (sum over the ion species) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total_fast_perpendicular\nFast (non-thermal) total ion (sum over the ion species) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].phi\nToroidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].psi_star_post_crash\nPsi* = psi - phi, after the sawtooth crashUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].psi_star_pre_crash\nPsi* = psi - phi, just before the sawtooth crashUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].q\nSafety factorData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].t_e\nElectron temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].brightness.data\nDataUnits: W.m^-2.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"soft_x_rays.channel[:].brightness.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].brightness.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.bucked\nFlag indicating if center stack elements bucked to one anotherData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.oh\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.pl\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.tf\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_oh\nRadial coordinate in OH layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_pl\nRadial coordinate in plug layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_tf\nRadial coordinate in TF layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.noslip\nFlag indicating if center stack elements are not allowed to slip with respect to one anotherData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.plug\nFlag indicating if center stack has a plugData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.oh\nChange in shape for OH structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.pl\nChange in shape for plug structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.tf\nChange in shape for TF structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.oh\nMaximum stress OH can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.pl\nMaximum stress plug can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.tf\nMaximum stress TF can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.oh\nStiffness of OH structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.pl\nStiffness of plug structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.tf\nStiffness of TF structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.oh\nAverage axial stress for OH layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.pl\nAverage axial stress for plug layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.tf\nAverage axial stress for TF layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.oh\nHoop stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.pl\nHoop stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.tf\nHoop stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.oh\nRadial stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.pl\nRadial stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.tf\nRadial stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.oh\nVon Mises stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.pl\nVon Mises stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.tf\nVon Mises stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].a\nAtomic mass measured by this channelUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].current\nCollected currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].photomultiplier_voltage\nVoltage applied to the photomultiplierUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].pressure_partial\nPartial pressure (calibrated data)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].time\nTimebase for the dynamic nodes of this channelUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].validity\nIndicator of the validity of the data. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].validity_timed\nIndicator of the validity of the data for each time slice. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Means problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning.)Data Type: INT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_mass.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.identifier\nID of the spectrometerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.name\nName of the spectrometerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].a\nArray of atomic massesUnits: Atomic Mass Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].current\nCollected currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.residual_spectrum[:].a\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.detector_dimensions\nTotal detector dimension in each direction (horizontal, vertical)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.pixel_dimensions\nPixel dimension in each direction (horizontal, vertical)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.pixel_n\nNumber of pixels in each direction (horizontal, vertical)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_position_parameter.data\nDataUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].detector_position_parameter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_position_parameter.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.curvature_radius\nCurvature radius of the spherical gratingUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.groove_density\nNumber of grooves per unit lengthUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.curvature_radius\nCurvature radius of the image surfaceUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].grating.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].intensity_spectrum.data\nDataUnits: (counts) s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_uv.channel[:].intensity_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].intensity_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.amplitude_parameter\nAmplitude of the line of sight position parameter oscillation (in case moving_mode/index = 1)Units: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.period\nPeriod of the line of sight oscillation (in case moving_mode/index = 1)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.position_parameter.data\nDataUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.position_parameter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.position_parameter.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].intensity.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].processed_line[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].radiance.data\nDataUnits: m^-2.s^-1.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].processed_line[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_uv.channel[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].object\nName of the object connected to the power supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity_timed.data\nDataData Type: INT_2D\nCoordinates: [\"spectrometer_uv.channel[:].wavelengths\", \"spectrometer_uv.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration.gain\nGainUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration.offset\nOffsetUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_uv.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue\nEtendue (geometric extent) of the optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.circular.ellipticity\nEllipticityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.circular.radius\nRadius of the circleUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.geometry_type\nType of geometry used to describe the image (1:'outline', 2:'circular')Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.circular.ellipticity\nEllipticityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.circular.radius\nRadius of the circleUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.geometry_type\nType of geometry used to describe the image (1:'outline', 2:'circular')Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_central\nCentral wavelength of the filterUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_width\nFilter transmission function width (at 90% level)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.output_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photon_count.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.photon_count.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photon_count.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.sensitivity\nPhotoelectric sensitivity of the detector. This is the conversion factor from the received power on the detector into electric voltage depending on the wavelengthUnits: V.W^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.wavelengths\nArray of wavelengths for radiance calibrationUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3\nThird dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.data\nInterpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector or head of an optic fibre). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phiUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.phi\nToroidal angle (oriented counter-clockwise when viewing from above) of interpolation knotsUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.r\nMajor radius of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.z\nHeight of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.voxel_map\nVoxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.Data Type: INT_3D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1\", \"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2\", \"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.voxels_n\nNumber of voxels defined in the voxel_map.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.with_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.with_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.with_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.without_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.without_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.without_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.grating\nNumber of grating lines per unit lengthUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.instrument_function\nArray of Gaussian widths and amplitudes which as a sum make up the instrument function. The instrument function is the shape that would be measured by a grating spectrometer if perfectly monochromatic line emission would be used as input. F(lambda) = 1 / sqrt (2*pi) * sum( instrumentfunction(1,i) / instrumentfunction(2,i) ) * exp( -lambda^2 / (2 * instrumentfunction(2,i)^2) ) ), whereby sum( instrumentfunction(1,i) ) = 1Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.data\nDataUnits: (counts) s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.data\nDataUnits: m^-2.s^-1.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.slit_width\nWidth of the slit (placed in the object focal plane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.gain\nGainUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.offset\nOffsetUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_fraction\nFraction of cold neutrals for this isotope (ncoldneutrals/(ncoldneutrals+nhotneutrals))Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_temperature\nTemperature of cold neutrals for this isotopeUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].density_ratio\nRatio of the density of neutrals of this isotope over the summed neutral densities of all other isotopes described in the ../isotope arrayData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_fraction\nFraction of hot neutrals for this isotope (nhotneutrals/(ncoldneutrals+nhotneutrals))Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_temperature\nTemperature of hot neutrals for this isotopeUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].label\nString identifying the species (H, D, T, He3, He4)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.signal_to_noise\nLog10 of the ratio of the powers in two bands, one with the spectral lines of interest (signal) the other without spectral lines (noise).Units: dB\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.validity\nIndicator of the validity of the isotope ratios for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.validity_timed\nIndicator of the validity of the isotope ratios as a function of time (0 means valid, negative values mean non-valid)Data Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.values\nValues of the light collection efficienciesData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].object_observed\nMain object observed by the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.b_field_modulus\nModulus of the magnetic field (always positive, irrespective of the sign convention for the B-field direction), obtained from Zeeman effect fitUnits: T\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_r\nLower Hybrid electric field component in the major radius directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_tor\nLower Hybrid electric field component in the toroidal directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_z\nLower Hybrid electric field component in the vertical directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.n_e\nElectron density, obtained from Stark broadening fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.temperature_cold_neutrals\nFit of cold neutrals temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.temperature_hot_neutrals\nFit of hot neutrals temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.velocity_cold_neutrals\nProjection of the cold neutral velocity along the line of sight, positive when going from first point to second point of the line of sightUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.velocity_hot_neutrals\nProjection of the hot neutral velocity along the line of sight, positive when going from first point to second point of the line of sightUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarizer.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer_active\nIndicator of whether a polarizer is present and active in the optical system (set to 1 in this case, set to 0 or leave empty ottherwise)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity\nIndicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity_timed.data\nDataData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.detector_layout\nLayout of the detector grid employed. Ex: '4x16', '4x32', '1x18'Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.centre\nCentre (in terms of absolute wavelength) of instrument functionUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.intensity\nScaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detectorUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.scale\nScale of Lorentzian instrument function (full width at half height)Units: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.sigma\nStandard deviation of Gaussian instrument functionUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.values\nExplicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a binned pixel of the detector, gives the detector pixel output in counts/seconds.Units: sr.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\nArray of wavelengths on which the instrument function is definedUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].wavelength\nWavelength of incoming photons on each horizontal pixel of this bin.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].z_pixel_range\nVertical pixel index range indicating the corresponding binned detector areaData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.camera_dimensions\nTotal camera dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.identifier\nID of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_dimensions\nPixel dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixels_n\nNumber of pixels in each direction (x1, x2)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.angle_bragg\nBragg angle of the crystalUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.cut\nMiller indices characterizing the cut of the crystal (can be of length 3 or 4)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.identifier\nID of the objectData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].crystal.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.surface\nSurface of the object, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.thickness\nThickness of the crystalUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.wavelength_bragg\nBragg wavelength of the crystalUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_width\nFull width of the object in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_width\nFull width of the object in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energies\nArray of energy values for tabulation of the detection efficiencyUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energy_bound_lower\nLower energy bound for the photon detection, for each pixel (horizontal, vertical)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energy_bound_upper\nUpper energy bound for the photon detection, for each pixel (horizontal, vertical)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].exposure_time\nExposure time of the measurementUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].counts_bin_n\nNumber of counts detected on each pixel/bin of the binned frame during one exposure timeData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].bin\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].counts_n\nNumber of counts detected on each pixel of the frame during one exposure timeData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.centre\nCentre (in terms of absolute wavelength) of instrument functionUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.intensity\nScaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detectorUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.scale\nScale of Lorentzian instrument function (full width at half height)Units: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.sigma\nStandard deviation of Gaussian instrument functionUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.values\nExplicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a pixel of the detector, gives the detector pixel output in counts/seconds.Units: sr.m\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\nArray of wavelengths on which the instrument function is definedUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.data\nDataUnits: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.data\nDataUnits: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.data\nDataUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].identifier\nID of the objectData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].surface\nSurface of the object, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_width\nFull width of the object in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_width\nFull width of the object in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].wavelength_frames\nWavelength of incoming photons on each pixel of the frames, mainly varying accross the horizontal dimension of the frame. However a 2D map of the wavelength is given since it is not constant vertically due to the elliptical curvature of the photon iso-surfacesUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].z_frames\nHeight of the observed zone at the focal plane in the plasma, corresponding to the vertical dimension of the frameUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_r\nMajor radius component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_tor\nToroidal component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_z\nVertical component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].volume\nVolume of the fragmentUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.atoms_n\nTotal number of atoms of the gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.flow_rate\nFlow rate of the gas at the injector exitUnits: atoms.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].fraction\nAtomic fraction of the speciesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.temperature\nGas temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].identifier\nIdentifier of the injectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].name\nName of the injectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.time_arrival\nArrival time at the optical pellet diagnostic, for each objectUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.atoms_n\nTotal number of atoms of desublimated gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.diameter\nPellet diameterUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.length\nPellet length (cylindrical pellet)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.atoms_n\nTotal number of atoms of desublimated gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_r\nMajor radius component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_shatter\nNorm of the velocity of the centre of mass of the pellet right before shatteringUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_tor\nToroidal component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_z\nVertical component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.atoms_n\nTotal number of atoms of the gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.flow_rate\nFlow rate of the gas at the injector exitUnits: atoms.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].fraction\nAtomic fraction of the speciesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.temperature\nGas temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.angle_major\nAngle between the cone direction and unitvectormajorUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.angle_minor\nAngle between the cone direction and unitvectorminorUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_angle\nImpact (or grazing) angle of the pellet with the shattering element. It is the complementary of the incidence angle with the element surface at the shattering locationUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].time_shatter\nArrival time at the shattering unitUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].time_trigger\nTime of trigger request to the power supply according to the DMS sequenceUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_r\nMajor radius component of the velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_tor\nToroidal component of the velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_z\nVertical component of the velocity velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.all_cleared\nTrue (1) if all stability limits are cleared, otherwise False (0)Data Type: INT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].cleared\nTrue (1) if a given stability limit is cleared, otherwise False (0)Data Type: INT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].fraction\nFraction of limit Data Type: FLT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.distance_inner_outer_separatrices.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.distance_inner_outer_separatrices.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.elongation.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.elongation.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.gap_limiter_wall.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.gap_limiter_wall.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.minor_radius.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.minor_radius.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_configuration.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_configuration.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.triangularity_lower.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.triangularity_lower.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.exponential.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.exponential.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.mitigation_valve.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.mitigation_valve.value\nValueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.a.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.a.value\nValueUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.label.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.label.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.z_n.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.z_n.value\nValueUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].tangency_radius.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].tangency_radius.value\nValueUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_additional.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_additional.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ec.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ec.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ic.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ec.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ec.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ic.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_lh.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_lh.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi_co_injected_ratio.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi_co_injected_ratio.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_total.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_lh.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_lh.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_nbi.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_nbi.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.kicks.occurrence.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.kicks.occurrence.value\nValueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.iron.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.lithium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.lithium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.neon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.neon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.deuterium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_4.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.hydrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.iron.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.krypton.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.lithium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.lithium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.neon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.neon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.nitrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.oxygen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tritium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.carbon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.deuterium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.deuterium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_3.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_4.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.hydrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.iron.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.krypton.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.q.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.helium_4.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.q.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.q.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_e.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_i_average.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_i_average.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.argon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.argon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.beryllium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.carbon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.dn_e_dt.value\nValueUnits: m^-3.s-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.isotope_fraction_hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.isotope_fraction_hydrogen.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.meff_hydrogenic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.meff_hydrogenic.value\nValueUnits: amu\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_e.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.argon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.beryllium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.carbon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.deuterium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.deuterium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_3.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_4.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.hydrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.iron.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.krypton.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.neon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_e.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_i_average.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_i_average.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.zeff.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.zeff.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.evaporation.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.evaporation.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float4d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].value.data\nDataUnits: mixed\nData Type: FLT_5D\nCoordinates: [\"1...N\", \"1...N\", \"1...N\", \"1...N\", \"temporary.dynamic_float5d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].value.data\nDataUnits: mixed\nData Type: FLT_6D\nCoordinates: [\"1...N\", \"1...N\", \"1...N\", \"1...N\", \"1...N\", \"temporary.dynamic_float6d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].value.data\nDataData Type: INT_1D\nCoordinates: [\"temporary.dynamic_integer1d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].value.data\nDataData Type: INT_2D\nCoordinates: [\"1...N\", \"temporary.dynamic_integer2d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].value.data\nDataData Type: INT_3D\nCoordinates: [\"1...N\", \"1...N\", \"temporary.dynamic_integer3d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.b_field_tor_vacuum_r.data\nDataUnits: T.m\nData Type: FLT_1D\nCoordinates: [\"tf.b_field_tor_vacuum_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.b_field_tor_vacuum_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_phi\nToroidal angles (relative to a reference point)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].cross_section.delta_r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_r\nMajor radii (relative to a reference point)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_z\nHeights (relative to a reference point)Units: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].cross_section.delta_r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.centres.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.centres.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.end_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.end_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.intermediate_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.intermediate_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.names\nName or description of every elementData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.start_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.start_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.types\nType of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circleData Type: INT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].resistance\nconductor resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].identifier\nAlphanumeric identifier of coil used for convenienceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].turns\nNumber of total turns in a toroidal field coil. May be a fraction when describing the coil connections.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coils_n\nNumber of coils around the torus, in case is_periodic = 1Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.delta_b_field_tor_vacuum_r.data\nDataUnits: T.m\nData Type: FLT_1D\nCoordinates: [\"tf.delta_b_field_tor_vacuum_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.delta_b_field_tor_vacuum_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.is_periodic\nFlag indicating whether coils are described one by one in the coil() structure (flag=0) or whether the coil structure represents only coils having different characteristics (flag = 1, n_coils must be filled in that case). In the latter case, the coil() sequence is repeated periodically around the torus.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.r0\nReference major radius of the device (from the official description of the device). This node is the placeholder for this official machine description quantity (typically the middle of the vessel at the equatorial midplane, although the exact definition may depend on the device)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].distance_separatrix_midplane.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].distance_separatrix_midplane.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].t_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].t_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"thomson_scattering.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.name\nIDS nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.occurrence\nIDS occurrenceData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.value\nValue of the boundary condition. For ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"transport_solver_numerics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.time_step.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.convergence.time_step.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.time_step.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2psi_drho_tor2\nSecond derivative of the poloidal flux profile with respect to the toroidal flux coordinateUnits: Wb.m^-2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dt.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dt.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dvolume_drho_tor_dt\nPartial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinateUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_drho_tor\nDerivative of the poloidal flux profile with respect to the toroidal flux coordinateUnits: Wb.m^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt\nDerivative of the poloidal flux profile with respect to timeUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt_cphi\nDerivative of the poloidal flux profile with respect to time, at constant toroidal fluxUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt_crho_tor_norm\nDerivative of the poloidal flux profile with respect to time, at constant normalised toroidal flux coordinateUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].drho_tor_dt\nPartial derivative of the toroidal flux coordinate profile with respect to timeUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].descriptions\nDescriptions of the restart filesData Type: STR_1D\nCoordinates: [\"transport_solver_numerics.restart_files[:].names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].names\nNames of the restart filesData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].name\nName of the control parameterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].value\nValue of the control parameterData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].name\nName of the control parameterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].value\nValue of the control parameterUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].d_dvolume_drho_tor_dt\nPartial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinateUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].drho_tor_dt\nPartial derivative of the toroidal flux coordinate profile with respect to timeUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].position\nPosition, in terms of the primary coordinate, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed (in case of a single boundary condition).Units: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].value\nValue of the boundary condition. For type/index = 1 to 3, only the first position in the vector is used. For type/index = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].coefficient[:].profile\nRadial profile of the numerical coefficientUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d2_dr2\nSecond order radial derivative with respect to the primary coordinateUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dr\nRadial derivative with respect to the primary coordinateUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt\nTime derivativeUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cphi\nDerivative with respect to time, at constant toroidal flux (for current diffusion equation)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cr\nDerivative with respect to time, at constant primary coordinate coordinate (for current diffusion equation)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.ion_index\nIf the primary quantity is related to a ion species, index of the corresponding species in the coreprofiles/profiles1d/ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.neutral_index\nIf the primary quantity is related to a neutral species, index of the corresponding species in the coreprofiles/profiles1d/neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.profile\nProfile of the primary quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.state_index\nIf the primary quantity is related to a particular state (of an ion or a neutral species), index of the corresponding state in the coreprofiles/profiles1d/ion (or neutral)/state arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_average.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_min.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step_min.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_min.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"turbulence.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].identifier\nIdentifier of this unit. Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : ic_antenna/a1/bumpers refers to the bumpers of the a1 IC antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].name\nName of the limiter unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].limiter.unit[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].phi_extensions\nSimplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].resistivity\nResistivity of the limiter unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].name\nName of the mobile unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].mobile.unit[:].outline[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].phi_extensions\nSimplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].resistivity\nResistivity of the mobile unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].identifiers\nIdentifiers of the components (described in the various gridsubsets). Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : icantenna/a1/bumpers refers to the bumpers of the a1 IC antennaData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].a_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].a_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].e_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].e_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].j_total[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].j_total[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].power_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Ohm.m\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].resistivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].values\nOne scalar value is provided per element in the grid subset.Units: Ohm.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: K\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: K\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].v_biasing[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.descriptions\nVerbose descriptionData Type: STR_1D\nCoordinates: [\"wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.indices\nInteger identifiers (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_1D\nCoordinates: [\"wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\nShort string identifiersData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].thickness[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_enclosed_volume\nVolume available to gas or plasma enclosed by the first wall contourUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_power_flux_peak.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.first_wall_power_flux_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_power_flux_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_surface_area\nFirst wall surface areaUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.current_tor\nToroidal current flowing in the vacuum vesselUnits: A\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.gas_puff\nGas puff rate (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.particle_flux_from_plasma\nParticle flux from the plasma (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.particle_flux_from_wall\nParticle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), in equivalent electronsUnits: s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.power_inner_target\nElectron power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.power_outer_target\nElectron power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.pumping_speed\nPumped particle flux (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].gas_puff\nGas puff rate for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].energies\nArray of energies of this incident species, on which the sputteringphysicalcoefficient is tabulatedUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].label\nString identifying the incident species (e.g. H, D, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].sputtering_chemical_coefficient\nEffective coefficient of chemical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident speciesData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].sputtering_physical_coefficient\nEffective coefficient of physical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species and for various energies (second dimension)Data Type: FLT_3D\nCoordinates: [\"1...3\", \"wall.global_quantities.neutral[:].incident_species[:].energies\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].label\nString identifying the species (e.g. H, D, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].particle_flux_from_plasma\nParticle flux from the plasma for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].particle_flux_from_wall\nParticle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Units: s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].pumping_speed\nPumped particle flux for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].recycling_energy_coefficient\nEnergy recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Data Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].recycling_particles_coefficient\nParticle recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Data Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].wall_inventory\nWall inventory, i.e. cumulated exchange of neutral species between plasma and wall from t = 0, positive if a species has gone to the wall, for that speciesData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_black_body\nBlack body radiated power emitted from the wall (emissivity is included)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_conducted\nPower conducted by the plasma onto the wallUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_convected\nPower convected by the plasma onto the wallUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_currents\nPower deposited on the wall due to electric currents (positive means power is deposited on the target)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_density_inner_target_max\nMaximum power density on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_density_outer_target_max\nMaximum power density on the outer targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_incident\nTotal power incident on the wall. This power is split in the various physical categories listed belowUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_inner_target_ion_total\nTotal ion (summed over ion species) power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_neutrals\nNet power from neutrals on the wall (positive means power is deposited on the wall)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_radiated\nNet radiated power from plasma onto the wall (incident-reflected)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_recombination_neutrals\nPower deposited on the wall due to recombination of neutrals into a ground state (e.g. molecules)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_recombination_plasma\nPower deposited on the wall due to recombination of plasma ionsUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_to_cooling\nPower to cooling systemsUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.temperature\nWall temperatureUnits: K\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.temperature_reference.data\nReference temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.temperature_reference.description\nDescription of how the reference temperature is defined : for which object, at which location, ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].electrons.power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].length\nRay/beam curvilinear lengthUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].phase.angle\nRotation angle for the phase ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].phase.curvature\nInverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)Units: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.psi\nPoloidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.theta\nPoloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.parallel\nNormalized power flow in the direction parallel to the magnetic fieldData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.perpendicular\nNormalized power flow in the direction perpendicular to the magnetic fieldData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_initial\nInitial power in the ray/beamUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].spot.angle\nRotation angle for the spot ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].spot.size\nSize of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r\nWave vector component in the major radius directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r_norm\nNormalized wave vector component in the major radius direction = k_r / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor\nWave vector component in the toroidal directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor_norm\nNormalized wave vector component in the toroidal direction = k_tor / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z\nWave vector component in the vertical directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z_norm\nNormalized wave vector component in the vertical direction = k_z / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_parallel\nParallel refractive indexData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_perpendicular\nPerpendicular refractive indexData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_tor\nToroidal wave number, contains a single value if varyingntor = 0 to avoid useless repetition constant values. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive ntor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.varying_n_tor\nFlag telling whether n_tor is constant along the ray path (0) or varying (1)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.minus[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.plus[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].current_tor\nWave driven toroidal current from a stand alone calculation (not consistent with other sources)Units: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].current_tor_n_tor\nWave driven toroidal current from a stand alone calculation (not consistent with other sources) per toroidal mode numberUnits: A\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.distribution_assumption\nAssumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS). Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].frequency\nWave frequencyUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].distribution_assumption\nAssumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS). Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].power\nTotal absorbed wave powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].power_n_tor\nAbsorbed wave power per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.antenna_name\nName of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.index_in_antenna\nIndex of the wave (starts at 1), separating different waves generated from a single antenna.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_parallel_density\nFlux surface averaged wave driven parallel current density = average(j.B) / B0, where B0 = vacuumtoroidalfield/b0.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_parallel_density_n_tor\nFlux surface averaged wave driven parallel current density, per toroidal mode numberUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_tor_inside\nWave driven toroidal current, inside a flux surfaceUnits: A\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_tor_inside_n_tor\nWave driven toroidal current, inside a flux surface, per toroidal mode numberUnits: A\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].k_perpendicular\nPerpendicular wave vector, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that kperpendicular = ave(kperpendicular.powerdensity) / ave(powerdensity), for every flux surface and every toroidal numberUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_density\nFlux surface averaged total absorbed wave power density (electrons + ion + fast populations)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_density_n_tor\nFlux surface averaged absorbed wave power density per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_inside\nTotal absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_inside_n_tor\nTotal absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.rho_tor\nToroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0Units: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.theta_geometric\nGeometrical poloidal angleUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.theta_straight\nStraight field line poloidal angleUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].power_density\nTotal absorbed wave power density (electrons + ion + fast populations)Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].power_density_n_tor\nAbsorbed wave power density per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"workflow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.time_end\nTermination time for the workflow main time loopUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].control_float\nArray of real workflow control parameters used by this component (component specific)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].control_integer\nArray of integer workflow control parameters used by this component (component specific)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].execution_mode\nComponent execution mode for current workflow cycle. 0 means the component is not executed and the workflow uses results from previous workflow cycle. 1 means the component is executed for this workflow cycle.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].index\nIndex of the component in the ../../../component arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].time_interval_elapsed\nSimulation time interval for which this component has last computed its resultsUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].time_interval_request\nSimulation time interval for which this component is requested to compute its resultsUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"deps.html#Ecosystem","page":"Ecosystem","title":"Ecosystem","text":"","category":"section"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"The FUSE project is built upon multiple Julia packages, many of which reside in the https://github.com/ProjectTorreyPines organization on GitHub.","category":"page"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"(Image: FUSE dependencies)","category":"page"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"ADAS [repo]\nBalanceOfPlantSurrogate [repo]\nCHEASE [repo]\nCoordinateConventions [repo]\nEPEDNN [repo]\nFiniteElementHermite [repo]\nFuseExchangeProtocol [repo]\nFuseUtils [repo]\nFusionMaterials [repo]\nIMAS [repo]\nIMASdd [repo]\nMXHEquilibrium [repo]\nMeshTools [repo]\nMillerExtendedHarmonic [repo]\nNEO [repo]\nNNeutronics [repo]\nQED [repo]\nRABBIT [repo]\nSimulationParameters [repo]\nTEQUILA [repo]\nTGLFNN [repo]\nTJLF [repo]\nThermalSystemModels [repo]\nVacuumFields [repo]","category":"page"},{"location":"install_saga.html#Getting-started-on-the-SAGA-cluster","page":"on SAGA","title":"Getting started on the SAGA cluster","text":"","category":"section"},{"location":"install_saga.html","page":"on SAGA","title":"on SAGA","text":"Get a SAGA account and ask to have a directory created for you under /mnt/beegfs/users/$USER\nInstall miniconda\ncd /mnt/beegfs/users/$USER\nwget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh\nsh Miniconda3-latest-Linux-x86_64.sh\nread and accept the license, and install under /mnt/beegfs/users/$USER/miniconda3, answer questions, and restart your shell\ninstall mamba for faster package management\nconda install -c conda-forge mamba\ninstall jupyterlab\nmamba install -c conda-forge jupyterlab\nSetup your environment to run CHEASE (optional)\nexport PATH=$PATH:/mnt/beegfs/users/meneghini/chease/src-f90\nCreate a symbolic link from /mnt/beegfs/users/$USER/julia/ to ~/.julia\nmkdir -p /mnt/beegfs/users/$USER/julia/dev\nln -s /mnt/beegfs/users/$USER/julia ~/.julia\n~/.julia is where the Julia will install itself by default, and this will trick it to install itself in the IR&D folder instead.\nFor convenience create also a symbolic link in your $HOME that points to the Julia dev folder:\nln -s /mnt/beegfs/users/$USER/julia/dev ~/julia_dev\nNow follow the standard Julia and FUSE installation instructions","category":"page"},{"location":"install_saga.html#Jupyter-on-SAGA-cluster","page":"on SAGA","title":"Jupyter on SAGA cluster","text":"","category":"section"},{"location":"install_saga.html","page":"on SAGA","title":"on SAGA","text":"Connect to saga and launch screen\nnote: Note\nYou can re-connect to an existing screen session with screen -r\nThen start the Jupyter lab server from the screen session (screen will keep jupyter running even when you log out)\njupyter lab --no-browser --port 55667\nCopy the token that you see on this session it should look something like token=1f1e0259cbc1..................\nOn your computer setup your ~/.ssh/config this way (need to do this only once):\nHost cybele cybele.gat.com\nHostname cybele.gat.com\nUser meneghini\nPort 2039\n\nHost sagae saga.gat.com\nHostname saga.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\nOn your computer start a tunnel going through cybele to saga\nssh -N -L localhost:33445:localhost:55667 sagae\nnote: Note\nKeep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.\nOn your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on saga. Use the token when prompted.","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.casename\nSort mnemonic name of the case being runType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.description\nLonger description of the case being runType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.init_from\nInitialize run fromType: Switch{Symbol}\nUnits: -\nOptions: ods, scalars","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.dd\ndd to initialize fromType: Entry{IMASdd.dd}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.time.pulse_shedule_time_basis\nTime basis used to discretize the pulse scheduleType: Entry{AbstractRange{Float64}}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.time.simulation_start\nTime at which the simulation startsType: Entry{Float64}\nUnits: s\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ods.filename\nODS.json file(s) from which equilibrium is loaded. Multiple comma-separated ODSs can be specified.Type: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.B0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Type: Entry{Float64}\nUnits: T","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.R0\nGeometric genter of the plasma. NOTE: This also scales the radial build layers.Type: Entry{Float64}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.Z0\nZ offset of the machine midplaneType: Entry{Float64}\nUnits: m\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.ϵ\nPlasma inverse aspect ratio (a/R0). NOTE: This also scales the radial build layers.Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.κ\nPlasma elongation. NOTE: If < 1.0 it defines the fraction of maximum controllable elongation estimate.Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.tilt\nTilt of the plasma boundary [MXH c0]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.δ\nTriangularity of the plasma boundary [MXH sin(s1)]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.ζ\nSquareness of the plasma boundary [MXH -s2]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.𝚶\nOvality of the plasma boundary [MXH c1]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.twist\nTwist of the plasma boundary [MXH c2]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.pressure_core\nOn axis pressureType: Entry{Float64}\nUnits: Pa","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.ip\nPlasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Type: Entry{Float64}\nUnits: A","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.xpoints\nX-points configurationType: Switch{Symbol}\nUnits: -\nOptions: lower, upper, double, none","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.ngrid\nResolution of the equilibrium gridType: Entry{Int64}\nUnits: -\nDefault: 129","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.field_null_surface\nψn value of the fieldnullsurface. Disable with 0.0Type: Entry{Float64}\nUnits: -\nDefault: 0.75","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.boundary_from\nThe starting r, z boundary taken fromType: Switch{Symbol}\nUnits: -\nOptions: scalars, MXH_params, rz_points, ods","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.MXH_params\nVector of MXH flatsType: Entry{Vector{Float64}}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.rz_points\nRZ boundary as Vector{Vector{Float64}}} : r = rzpoints[1], z = rz_points[2]Type: Entry{Vector{Vector{Float64}}}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.plasma_mode\nPlasma configurationType: Switch{Symbol}\nUnits: -\nOptions: H_mode, L_mode\nDefault: H_mode","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.w_ped\nPedestal width expressed in fraction of ψₙType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_value\nValue based on setup methodType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_setting\nWay to set the electron densityType: Switch{Symbol}\nUnits: -\nOptions: ne_ped, ne_line, greenwald_fraction, greenwald_fraction_ped","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ne_sep_to_ped_ratio\nRatio used to set the sepeartrix density based on the pedestal densityType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ne_core_to_ped_ratio\nRatio used to set the core density based on the pedestal densityType: Entry{Float64}\nUnits: -\nDefault: 1.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_shaping\nDensity shaping factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.T_ratio\nTi/Te ratioType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.T_shaping\nTemperature shaping factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.Te_sep\nSeparatrix temperatureType: Entry{Float64}\nUnits: eV\nDefault: 80.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.zeff\nEffective ion chargeType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.rot_core\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityType: Entry{Float64}\nUnits: s^-1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ngrid\nResolution of the core_profiles gridType: Entry{Int64}\nUnits: -\nDefault: 101","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.bulk\nBulk ion speciesType: Entry{Symbol}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.impurity\nImpurity ion speciesType: Entry{Symbol}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.helium_fraction\nHelium density / electron density fractionType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ejima\nEjima coefficientType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.polarized_fuel_fraction\nSpin polarized fuel fractionType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.n_coils_inside\nNumber of PF coils inside of the TFType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.n_coils_outside\nNumber of PF coils outside of the TFType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.technology\nPF coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.side\nSide of the vacuum vessel where the plasma is limited at breakdownType: Switch{Symbol}\nUnits: -\nOptions: hfs, lfs","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.ends_at\nUntil when does the rampup lastsType: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.diverted_at\nTime at which x-point is formed and plasma can peel-off the wallType: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.power_launched\nBeam powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.3","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.beam_energy\nBeam energyType: Entry{Float64}\nUnits: eV","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.beam_mass\nBeam massType: Entry{Float64}\nUnits: AU\nDefault: 2.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.toroidal_angle\nToroidal angle of injectionType: Entry{Float64}\nUnits: rad","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.efficiency_conversion\nConversion efficiency of electric power to neutral beam powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.efficiency_transmission\nTransmission efficiency of neutral beam from source to portType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ec_launcher.1.power_launched\nEC launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.5","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.025","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.frequency\nFrequency of pellets launchedType: Entry{Float64}\nUnits: Hz","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.5","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.shape\nThe pellet geometryType: Switch{Symbol}\nUnits: -\nOptions: spherical, cylindrical, rectangular\nDefault: spherical","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.species\nPellet speciesType: Switch{Symbol}\nUnits: -\nOptions: H, D, T, DT, C, Ne","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.size\nVector of geometric dimensions describing the pellet size for a given shape (spherical: [r], cylindrical: [d, l], rectangular: [x,y,z])Type: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ic_antenna.1.power_launched\nIC launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_coupling\nCoupling efficiency of launched microwave power to the plasmaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.lh_antenna.1.power_launched\nLH launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.8","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_coupling\nCoupling efficiency of launched microwave power to the plasmaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.hcd.power_scaling_cost_function\nEC, IC, LH, NB power optimization cost function, takes dd as input. Eg. dd -> (1.0 - IMAS.tauethermal(dd) / IMAS.taueh98(dd))Type: Entry{Function}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.name\nName of the layerType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.thickness\nRelative thickness of the layer (layers actual thickness is scaled to match plasma R0)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.material\nMaterial of the layerType: Switch{Symbol}\nUnits: -\nOptions: tungsten, aluminum, graphite, nbti, flibe, water, plasma, lithium_lead, nb3sn_iter, nb3sn, vacuum, rebco, steel, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.shape\nShape of the layerType: Switch{IMAS.BuildLayerShape}\nUnits: -\nOptions: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.type\nType of the layerType: Switch{IMAS.BuildLayerType}\nUnits: -\nOptions: blanket, cryostat, gap, vessel, tf, oh, shield, port, wall, plasma, divertor","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.side\nSide of the layerType: Switch{IMAS.BuildLayerSide}\nUnits: -\nOptions: hfs, in, lfs, out, lhfs","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.plasma_gap\nFraction of vacuum gap between first wall and plasma separatrix in radial buildType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.symmetric\nIs the build up-down symmetricType: Entry{Bool}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.divertors\nDivertors configurationType: Switch{Symbol}\nUnits: -\nOptions: lower, upper, double, none, from_x_points\nDefault: from_x_points","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.n_first_wall_conformal_layers\nNumber of layers that are conformal to the first wallType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.bucked\nFlag for bucked boundary conditions between TF and OH (and center plug, if present)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.noslip\nFlag for no slip conditions between TF and OH (and center plug, if present)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.plug\nFlag for center plugType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.n_coils\nNumber of TF coilsType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.shape\nShape of the TF coilsType: Switch{IMAS.BuildLayerShape}\nUnits: -\nOptions: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.tf.ripple\nFraction of toroidal field ripple evaluated at the outermost radius of the plasma chamberType: Entry{Float64}\nUnits: -\nDefault: 0.01","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.technology\nTF coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.oh.n_coils\nNumber of OH coilsType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.oh.technology\nOH coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.bop.cycle_type\nThermal cycle typeType: Switch{Symbol}\nUnits: -\nOptions: rankine, brayton\nDefault: rankine","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.power_electric_net\nNet electric power generated by the fusion power plantType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.flattop_duration\nDuration of the flattop (use Inf for steady-state)Type: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.log10_flattop_duration\nLog10 value of the duration of the flattop (use Inf for steady-state). Preferred over flattop_duration for optimization studies.Type: Entry{Float64}\nUnits: log10(s)","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.tritium_breeding_ratio\nTritium breeding ratio of the whole plantType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.cost\nTotal FPP costType: Entry{Float64}\nUnits: $M","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.ne_peaking\nOn-axis electron density / volume-averaged electron denstiyType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.q_pol_omp\nPoloidal heat flux at the outer midplaneType: Entry{Float64}\nUnits: W/m^2","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.lh_power_threshold_fraction\nFraction of the LH power thresholdType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.h98y2\nH98y2 ITER elmy H-mode confinement scaling factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.hds03\nPetty 2003 H-mode thermal energy confinement scaling factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.beta_normal\nNormalized total plasma beta (MHD)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.Psol_R\nPsol / RType: Entry{Float64}\nUnits: W/m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.q95\nEdge safety factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.requirements.coil_j_margin\nMagnet coil Jcrit / JmaxType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.requirements.coil_stress_margin\nMagnet coil yieldstress / maxstressType: Entry{Float64}\nUnits: -\nDefault: 0.2","category":"page"},{"location":"license.html","page":"License","title":"License","text":" Apache License\n Version 2.0, January 2004\n http://www.apache.org/licenses/","category":"page"},{"location":"license.html","page":"License","title":"License","text":"TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Definitions.\n\"License\" shall mean the terms and conditions for use, reproduction, and distribution as defined by Sections 1 through 9 of this document.\n\"Licensor\" shall mean the copyright owner or entity authorized by the copyright owner that is granting the License.\n\"Legal Entity\" shall mean the union of the acting entity and all other entities that control, are controlled by, or are under common control with that entity. For the purposes of this definition, \"control\" means (i) the power, direct or indirect, to cause the direction or management of such entity, whether by contract or otherwise, or (ii) ownership of fifty percent (50%) or more of the outstanding shares, or (iii) beneficial ownership of such entity.\n\"You\" (or \"Your\") shall mean an individual or Legal Entity exercising permissions granted by this License.\n\"Source\" form shall mean the preferred form for making modifications, including but not limited to software source code, documentation source, and configuration files.\n\"Object\" form shall mean any form resulting from mechanical transformation or translation of a Source form, including but not limited to compiled object code, generated documentation, and conversions to other media types.\n\"Work\" shall mean the work of authorship, whether in Source or Object form, made available under the License, as indicated by a copyright notice that is included in or attached to the work (an example is provided in the Appendix below).\n\"Derivative Works\" shall mean any work, whether in Source or Object form, that is based on (or derived from) the Work and for which the editorial revisions, annotations, elaborations, or other modifications represent, as a whole, an original work of authorship. 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You are solely responsible for determining the appropriateness of using or redistributing the Work and assume any risks associated with Your exercise of permissions under this License.\nLimitation of Liability. In no event and under no legal theory, whether in tort (including negligence), contract, or otherwise, unless required by applicable law (such as deliberate and grossly negligent acts) or agreed to in writing, shall any Contributor be liable to You for damages, including any direct, indirect, special, incidental, or consequential damages of any character arising as a result of this License or out of the use or inability to use the Work (including but not limited to damages for loss of goodwill, work stoppage, computer failure or malfunction, or any and all other commercial damages or losses), even if such Contributor has been advised of the possibility of such damages.\nAccepting Warranty or Additional Liability. While redistributing the Work or Derivative Works thereof, You may choose to offer, and charge a fee for, acceptance of support, warranty, indemnity, or other liability obligations and/or rights consistent with this License. However, in accepting such obligations, You may act only on Your own behalf and on Your sole responsibility, not on behalf of any other Contributor, and only if You agree to indemnify, defend, and hold each Contributor harmless for any liability incurred by, or claims asserted against, such Contributor by reason of your accepting any such warranty or additional liability.","category":"page"},{"location":"license.html","page":"License","title":"License","text":"END OF TERMS AND CONDITIONS","category":"page"},{"location":"license.html","page":"License","title":"License","text":"APPENDIX: How to apply the Apache License to your work.","category":"page"},{"location":"license.html","page":"License","title":"License","text":" To apply the Apache License to your work, attach the following\n boilerplate notice, with the fields enclosed by brackets \"[]\"\n replaced with your own identifying information. (Don't include\n the brackets!) The text should be enclosed in the appropriate\n comment syntax for the file format. We also recommend that a\n file or class name and description of purpose be included on the\n same \"printed page\" as the copyright notice for easier\n identification within third-party archives.","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Copyright 2024 General Atomics","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Licensed under the Apache License, Version 2.0 (the \"License\"); you may not use this file except in compliance with the License. You may obtain a copy of the License at","category":"page"},{"location":"license.html","page":"License","title":"License","text":" http://www.apache.org/licenses/LICENSE-2.0","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an \"AS IS\" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.","category":"page"},{"location":"pubs.html#Publications","page":"Publications","title":"Publications","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"📜 ArXiv preprint publication","category":"page"},{"location":"pubs.html#Taks/Posters","page":"Publications","title":"Taks/Posters","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Overview presentation","category":"page"},{"location":"pubs.html#APS-DPP-2024","page":"Publications","title":"APS DPP 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: digital twin for tokamak fusion power plant design and operations\n📊 Lyons Magnetohydrodynamics and electromagnetics in the FUSE integrated-modeling framework\n📊 Ghiozzi Risk minimization as a novel optimization objective in FUSE\n📊 Dose Predictions of heat and neutron loads onto FPP first walls in FUSE\n🎤 Slendebroek Optimizing fusion power plant designs for +/- triangularity through FUSE simulations","category":"page"},{"location":"pubs.html#IMEG-2024","page":"Publications","title":"IMEG 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini The FUSE framework and related IMAS activities","category":"page"},{"location":"pubs.html#Juliacon-2024","page":"Publications","title":"Juliacon 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Slendebroek The FUSE framework and its use for fusion power plant design optimization","category":"page"},{"location":"pubs.html#Sherwood-2024","page":"Publications","title":"Sherwood 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: digital twin for tokamak fusion power plant design and operations","category":"page"},{"location":"pubs.html#IMEG-2023","page":"Publications","title":"IMEG 2023","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: A Modern Framework for Integrated Fusion Simulations","category":"page"},{"location":"examples.html#Worked-examples","page":"Examples","title":"Worked examples","text":"","category":"section"},{"location":"examples.html","page":"Examples","title":"Examples","text":"FUSE Jupyter examples are available and can be cloned to the current working directory with:","category":"page"},{"location":"examples.html","page":"Examples","title":"Examples","text":"fusebot install_examples","category":"page"},{"location":"examples.html","page":"Examples","title":"Examples","text":"To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.","category":"page"},{"location":"install_omega.html#Getting-started-on-the-OMEGA-cluster","page":"on OMEGA","title":"Getting started on the OMEGA cluster","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Install miniconda\ncd # in your home folder\nwget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh\nsh Miniconda3-latest-Linux-x86_64.sh\nread and accept the license, and install under $HOME/miniconda3, answer questions, and restart your shell\ninstall mamba for faster package management\n$HOME/miniconda3/bin/conda install -c conda-forge mamba\nnote: Note\nWe use the full conda path to avoid picking up the system conda install. There is no system-wide mamba executable, so that's not necessary when running mamba.\ninstall jupyterlab\nmamba install -c conda-forge jupyterlab\nRemove module load defaults from your ~/.bashrc This module is used to run experimental tools like review+, efit_veiwer, etc... but it does not play well with the Julia executable. (alternatively you'll have to module purge or module unload defaults)\nNow follow the standard Julia and FUSE installation instructions\nSetup a multi-threaded Jupyter Julia kernel that does not take the whole login node\nexport JULIA_NUM_THREADS=10\nfusebot install_IJulia\n\nexport JULIA_NUM_THREADS=40\nfusebot install_IJulia\nOMEGA login nodes are a shared resource. Each login node has 40 cores. This will setup a Jupyter Julia kernel with both 10 and 40 threads. Use 10 threads on login nodes and 40 threads on worker nodes.","category":"page"},{"location":"install_omega.html#Distributed.jl-on-OMEGA","page":"on OMEGA","title":"Distributed.jl on OMEGA","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"We have found issues when trying to run parallel jobs using Distributed.jl on OMEGA. The fix for this is simple: don't use the Main environment, rather activate a separate environment.","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"This can be easily by doing the following in the first cell of your Jupyter notebook:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"using Pkg\nPkg.activate(\"$HOME/julia_runs/my_run\") # this is key, to avoid using the Main FUSE environment\nPkg.add((\"Plots\", \"FUSE\"))","category":"page"},{"location":"install_omega.html#Three-ways-to-run-parallel-jobs","page":"on OMEGA","title":"Three ways to run parallel jobs","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Keep in mind that each worker node on OMEGA has 128 CPUs","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Screen + Jupyter on the login node, workers on the worker nodes\nOK when the master process will not be doing a lot of work, and we need multiple nodes\nHere we will use the FUSE.parallel_environment(\"omega\", ...) call.\nScreen on the login node, Jupyter and workers on one worker node\nOK when the master process will be doing a lot of work, and we don't need more than one node\nHere we will use the FUSE.parallel_environment(\"localhost\", ...) call.\nScreen on the login node, Jupyter on a worker node, workers on different worker nodes\nOK when the master process will be doing a lot of work, and we need multiple nodes\nThis is more complex, and finicky. Avoid if possible.\nHere we will use the FUSE.parallel_environment(\"omega\", ...) call.","category":"page"},{"location":"install_omega.html#FUSE-on-OMEGA-cluster","page":"on OMEGA","title":"FUSE on OMEGA cluster","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Connect to omega and launch screen\nnote: Note\nYou can re-connect to an existing screen session with screen -r\nIf (and only if) you want to run Jupyter on a worker node do as follows:\nsrun --partition=ga-ird --nodes=1 --time=4-00:00:00 --pty bash -l\nnote: Note\nUse the queue, time, CPU, and memory limits that make the most sense for your application see these instructions for help\nThen start the Jupyter lab server from the screen session (screen will keep jupyter running even when you log out)\njupyter lab --no-browser --port 55667\nCopy the token that you see on this session it should look something like token=1f1e0259cbc1..................\nOn your computer setup your ~/.ssh/config this way (need to do this only once):\nHost cybele cybele.gat.com\nHostname cybele.gat.com\nUser meneghini\nPort 2039\n\nHost omegae omega.gat.com\nHostname omega.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\n\n# change XX to the worker node number you've been assigned to\nHost omegaXX omegaXX.gat.com\nHostname omegaXX.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\nOn your computer start a tunnel going through cybele to omega\nssh -N -L localhost:33445:localhost:55667 omegae\nnote: Note\nKeep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.\nOn your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on omega. Use the token when prompted.","category":"page"},{"location":"install_omega.html#Using-Revise-on-OMEGA","page":"on OMEGA","title":"Using Revise on OMEGA","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"When working on omega it seems ones need to manually trigger revise to pick up code changes:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"import Revise\nRevise.revise() # manual trigger","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"This is even if setting JULIA_REVISE_POLL=1","category":"page"},{"location":"install_omega.html#Using-GACODE-on-OMEGA-with-Julia","page":"on OMEGA","title":"Using GACODE on OMEGA with Julia","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Julia may be incompatible with some environments and will crash when launched. This is the case for the GACODE environment on OMEGA. To be able to run both GACODE and Julia on OMEGA (eg. to run NEO and TGLF) do the following:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"module load atom\nmodule unload gcc\nmodule unload env","category":"page"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"CurrentModule = IMAS","category":"page"},{"location":"dd.html#IMAS-data-structure","page":"Data Structure","title":"IMAS data structure","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"FUSE data is organized into hierarchical Interface Data Structures (IDSs), according to the ITER IMAS ontology. In addition to the usual IMAS IDSs (which we include on a need-by-need basis) FUSE also defines some of its own IDSs, to hold data that does not (yet?) fit into IMAS. Notable examples are the build, solid_mechanics, balance_of_plant, and costing IDSs.","category":"page"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"dd = IMAS.dd() (which stands for \"data dictionary\") is the root of the FUSE data structure","category":"page"},{"location":"dd.html#amns-data","page":"Data Structure","title":"amns data","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.amns_data{Float64} # hide","category":"page"},{"location":"dd.html#b-field-non-axisymmetric","page":"Data Structure","title":"b field non axisymmetric","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.b_field_non_axisymmetric{Float64} # hide","category":"page"},{"location":"dd.html#balance-of-plant","page":"Data Structure","title":"balance of plant","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.balance_of_plant{Float64} # hide","category":"page"},{"location":"dd.html#barometry","page":"Data Structure","title":"barometry","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.barometry{Float64} # hide","category":"page"},{"location":"dd.html#blanket","page":"Data Structure","title":"blanket","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.blanket{Float64} # hide","category":"page"},{"location":"dd.html#bolometer","page":"Data Structure","title":"bolometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.bolometer{Float64} # hide","category":"page"},{"location":"dd.html#bremsstrahlung-visible","page":"Data Structure","title":"bremsstrahlung visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.bremsstrahlung_visible{Float64} # hide","category":"page"},{"location":"dd.html#build","page":"Data Structure","title":"build","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.build{Float64} # hide","category":"page"},{"location":"dd.html#calorimetry","page":"Data Structure","title":"calorimetry","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.calorimetry{Float64} # hide","category":"page"},{"location":"dd.html#camera-ir","page":"Data Structure","title":"camera ir","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_ir{Float64} # hide","category":"page"},{"location":"dd.html#camera-visible","page":"Data Structure","title":"camera visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_visible{Float64} # hide","category":"page"},{"location":"dd.html#camera-x-rays","page":"Data Structure","title":"camera x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#charge-exchange","page":"Data Structure","title":"charge exchange","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.charge_exchange{Float64} # hide","category":"page"},{"location":"dd.html#coils-non-axisymmetric","page":"Data Structure","title":"coils non axisymmetric","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.coils_non_axisymmetric{Float64} # hide","category":"page"},{"location":"dd.html#controllers","page":"Data Structure","title":"controllers","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.controllers{Float64} # hide","category":"page"},{"location":"dd.html#core-instant-changes","page":"Data Structure","title":"core instant changes","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_instant_changes{Float64} # hide","category":"page"},{"location":"dd.html#core-profiles","page":"Data Structure","title":"core profiles","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_profiles{Float64} # hide","category":"page"},{"location":"dd.html#core-sources","page":"Data Structure","title":"core sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_sources{Float64} # hide","category":"page"},{"location":"dd.html#core-transport","page":"Data Structure","title":"core transport","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_transport{Float64} # hide","category":"page"},{"location":"dd.html#costing","page":"Data Structure","title":"costing","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.costing{Float64} # hide","category":"page"},{"location":"dd.html#cryostat","page":"Data Structure","title":"cryostat","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.cryostat{Float64} # hide","category":"page"},{"location":"dd.html#dataset-description","page":"Data Structure","title":"dataset description","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.dataset_description{Float64} # hide","category":"page"},{"location":"dd.html#dataset-fair","page":"Data Structure","title":"dataset fair","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.dataset_fair{Float64} # hide","category":"page"},{"location":"dd.html#disruption","page":"Data Structure","title":"disruption","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.disruption{Float64} # hide","category":"page"},{"location":"dd.html#distribution-sources","page":"Data Structure","title":"distribution sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.distribution_sources{Float64} # hide","category":"page"},{"location":"dd.html#distributions","page":"Data Structure","title":"distributions","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.distributions{Float64} # hide","category":"page"},{"location":"dd.html#divertors","page":"Data Structure","title":"divertors","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.divertors{Float64} # hide","category":"page"},{"location":"dd.html#ec-launchers","page":"Data Structure","title":"ec launchers","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ec_launchers{Float64} # hide","category":"page"},{"location":"dd.html#ece","page":"Data Structure","title":"ece","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ece{Float64} # hide","category":"page"},{"location":"dd.html#edge-profiles","page":"Data Structure","title":"edge profiles","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_profiles{Float64} # hide","category":"page"},{"location":"dd.html#edge-sources","page":"Data Structure","title":"edge sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_sources{Float64} # hide","category":"page"},{"location":"dd.html#edge-transport","page":"Data Structure","title":"edge transport","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_transport{Float64} # hide","category":"page"},{"location":"dd.html#em-coupling","page":"Data Structure","title":"em coupling","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.em_coupling{Float64} # hide","category":"page"},{"location":"dd.html#equilibrium","page":"Data Structure","title":"equilibrium","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.equilibrium{Float64} # hide","category":"page"},{"location":"dd.html#ferritic","page":"Data Structure","title":"ferritic","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ferritic{Float64} # hide","category":"page"},{"location":"dd.html#focs","page":"Data Structure","title":"focs","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.focs{Float64} # hide","category":"page"},{"location":"dd.html#gas-injection","page":"Data Structure","title":"gas injection","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gas_injection{Float64} # hide","category":"page"},{"location":"dd.html#gas-pumping","page":"Data Structure","title":"gas pumping","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gas_pumping{Float64} # hide","category":"page"},{"location":"dd.html#gyrokinetics-local","page":"Data Structure","title":"gyrokinetics local","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gyrokinetics_local{Float64} # hide","category":"page"},{"location":"dd.html#hard-x-rays","page":"Data Structure","title":"hard x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.hard_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#ic-antennas","page":"Data Structure","title":"ic antennas","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ic_antennas{Float64} # hide","category":"page"},{"location":"dd.html#interferometer","page":"Data Structure","title":"interferometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.interferometer{Float64} # hide","category":"page"},{"location":"dd.html#iron-core","page":"Data Structure","title":"iron core","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.iron_core{Float64} # hide","category":"page"},{"location":"dd.html#langmuir-probes","page":"Data Structure","title":"langmuir probes","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.langmuir_probes{Float64} # hide","category":"page"},{"location":"dd.html#lh-antennas","page":"Data Structure","title":"lh antennas","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.lh_antennas{Float64} # hide","category":"page"},{"location":"dd.html#magnetics","page":"Data Structure","title":"magnetics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.magnetics{Float64} # hide","category":"page"},{"location":"dd.html#mhd","page":"Data Structure","title":"mhd","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mhd{Float64} # hide","category":"page"},{"location":"dd.html#mhd-linear","page":"Data Structure","title":"mhd linear","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mhd_linear{Float64} # hide","category":"page"},{"location":"dd.html#mse","page":"Data Structure","title":"mse","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mse{Float64} # hide","category":"page"},{"location":"dd.html#nbi","page":"Data Structure","title":"nbi","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.nbi{Float64} # hide","category":"page"},{"location":"dd.html#neutron-diagnostic","page":"Data Structure","title":"neutron diagnostic","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.neutron_diagnostic{Float64} # hide","category":"page"},{"location":"dd.html#neutronics","page":"Data Structure","title":"neutronics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.neutronics{Float64} # hide","category":"page"},{"location":"dd.html#ntms","page":"Data Structure","title":"ntms","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ntms{Float64} # hide","category":"page"},{"location":"dd.html#operational-instrumentation","page":"Data Structure","title":"operational instrumentation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.operational_instrumentation{Float64} # hide","category":"page"},{"location":"dd.html#pellets","page":"Data Structure","title":"pellets","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pellets{Float64} # hide","category":"page"},{"location":"dd.html#pf-active","page":"Data Structure","title":"pf active","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_active{Float64} # hide","category":"page"},{"location":"dd.html#pf-passive","page":"Data Structure","title":"pf passive","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_passive{Float64} # hide","category":"page"},{"location":"dd.html#pf-plasma","page":"Data Structure","title":"pf plasma","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_plasma{Float64} # hide","category":"page"},{"location":"dd.html#plasma-initiation","page":"Data Structure","title":"plasma initiation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.plasma_initiation{Float64} # hide","category":"page"},{"location":"dd.html#polarimeter","page":"Data Structure","title":"polarimeter","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.polarimeter{Float64} # hide","category":"page"},{"location":"dd.html#pulse-schedule","page":"Data Structure","title":"pulse schedule","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pulse_schedule{Float64} # hide","category":"page"},{"location":"dd.html#radiation","page":"Data Structure","title":"radiation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.radiation{Float64} # hide","category":"page"},{"location":"dd.html#real-time-data","page":"Data Structure","title":"real time data","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.real_time_data{Float64} # hide","category":"page"},{"location":"dd.html#reflectometer-fluctuation","page":"Data Structure","title":"reflectometer fluctuation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.reflectometer_fluctuation{Float64} # hide","category":"page"},{"location":"dd.html#reflectometer-profile","page":"Data Structure","title":"reflectometer profile","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.reflectometer_profile{Float64} # hide","category":"page"},{"location":"dd.html#refractometer","page":"Data Structure","title":"refractometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.refractometer{Float64} # hide","category":"page"},{"location":"dd.html#requirements","page":"Data Structure","title":"requirements","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.requirements{Float64} # hide","category":"page"},{"location":"dd.html#runaway-electrons","page":"Data Structure","title":"runaway electrons","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.runaway_electrons{Float64} # hide","category":"page"},{"location":"dd.html#sawteeth","page":"Data Structure","title":"sawteeth","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.sawteeth{Float64} # hide","category":"page"},{"location":"dd.html#soft-x-rays","page":"Data Structure","title":"soft x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.soft_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#solid-mechanics","page":"Data Structure","title":"solid mechanics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.solid_mechanics{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-mass","page":"Data Structure","title":"spectrometer mass","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_mass{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-uv","page":"Data Structure","title":"spectrometer uv","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_uv{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-visible","page":"Data Structure","title":"spectrometer visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_visible{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-x-ray-crystal","page":"Data Structure","title":"spectrometer x ray crystal","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_x_ray_crystal{Float64} # hide","category":"page"},{"location":"dd.html#spi","page":"Data Structure","title":"spi","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spi{Float64} # hide","category":"page"},{"location":"dd.html#stability","page":"Data Structure","title":"stability","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.stability{Float64} # hide","category":"page"},{"location":"dd.html#summary","page":"Data Structure","title":"summary","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.summary{Float64} # hide","category":"page"},{"location":"dd.html#temporary","page":"Data Structure","title":"temporary","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.temporary{Float64} # hide","category":"page"},{"location":"dd.html#tf","page":"Data Structure","title":"tf","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.tf{Float64} # hide","category":"page"},{"location":"dd.html#thomson-scattering","page":"Data Structure","title":"thomson scattering","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.thomson_scattering{Float64} # hide","category":"page"},{"location":"dd.html#transport-solver-numerics","page":"Data Structure","title":"transport solver numerics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.transport_solver_numerics{Float64} # hide","category":"page"},{"location":"dd.html#turbulence","page":"Data Structure","title":"turbulence","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.turbulence{Float64} # hide","category":"page"},{"location":"dd.html#wall","page":"Data Structure","title":"wall","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.wall{Float64} # hide","category":"page"},{"location":"dd.html#waves","page":"Data Structure","title":"waves","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.waves{Float64} # hide","category":"page"},{"location":"dd.html#workflow","page":"Data Structure","title":"workflow","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.workflow{Float64} # hide","category":"page"},{"location":"index.html#FUSE.jl","page":"Main","title":"FUSE.jl","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE (FUsion Synthesis Engine) is an open-source framework for the integrated design of Fusion Power Plants (FPP). Originally developed by General Atomics, FUSE is now publicly available under the Apache 2.0 license.","category":"page"},{"location":"index.html#Upcoming-2024-Code-Camp","page":"Main","title":"📢 Upcoming 2024 Code Camp 📢","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Join the FUSE community and help shape the future of Fusion Power Plant design:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Date: Dec 9th - 13th\nLocation: In person @ General Atomics\nSeats: Limited to 40 participants - 🔥 REGISTER TODAY!","category":"page"},{"location":"index.html#Resources","page":"Main","title":"Resources","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Here are some key resources for getting started with FUSE:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"📚 Online documentation\n📜 Preprint publication\n🆘 Discord community\n🗒️ Weekly devs meeting minutes","category":"page"},{"location":"index.html#Objectives","page":"Main","title":"Objectives","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE aims to achieve the following objectives:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"⚡ Provide a highly efficient, modular framework that tightly couples models across different domains.\n🧩 Integrate plasma physics, engineering, control, balance of plant, and costing systems.\n🤖 Leverage machine learning to overcome the typical fidelity/speed tradeoff in simulations.\n⏱️ Support both stationary and time-dependent simulations.\n💻 Harness parallelism and high-performance computing (HPC) for large-scale studies.\n🎯 Perform multi-objective constrained optimization to explore design tradeoffs.\n🔍 Enable comprehensive sensitivity analysis and uncertainty quantification.","category":"page"},{"location":"index.html#Basic-Concepts","page":"Main","title":"Basic Concepts","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE is entirely written in Julia and is structured around the following core concepts:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"📂 Data storage: All data is stored in the dd structure, which follows the ITER IMAS ontology.\n🧠 Actors: The core components of FUSE simulations are physics and engineering actors.\n🕹️ Control: Actor functionality is governed by act parameters.\n🚀 Initialization: The data structure can be initialized from 0D ini parameters.\n🔧 Use cases: FUSE includes templates for various machines (e.g., FPP, ITER, ARC).\n🔄 Workflows: Self-contained studies and optimizations are conducted via workflows, typically involving multiple FUSE simulations.\n🌍 Interoperability: FUSE interfaces with existing modeling tools like OMFIT/OMAS and the IMAS ecosystem.","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"A diagram illustrating these concepts is provided below: (Image: FUSE Diagram)","category":"page"},{"location":"index.html#Usage-Example","page":"Main","title":"Usage Example","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Here’s a simple example of setting up and running a FUSE simulation in Julia:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"using FUSE\n\n# Obtain `ini` and `act` parameters for a specific use case\nini, act = FUSE.case_parameters(:FPP)\n\n# Initialize the `dd` structure with 0D parameters\ndd = FUSE.init(ini, act)\n\n# Run a stationary plasma actor simulation\nFUSE.ActorStationaryPlasma(dd, act)\n\n# Get an overview of the simulation results\nFUSE.digest(dd)","category":"page"},{"location":"index.html#Installation","page":"Main","title":"Installation","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE and its related packages are available through the FuseRegistry. To install:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Install Julia\nAdd the FuseRegistry and General registries, then install FUSE:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"using Pkg\nPkg.Registry.add(RegistrySpec(url=\"https://github.com/ProjectTorreyPines/FuseRegistry.jl.git\"))\nPkg.Registry.add(\"General\")\nPkg.add(\"FUSE\")","category":"page"},{"location":"index.html#Citation","page":"Main","title":"Citation","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Please cite this work as follows:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"@article{meneghini2024fuse,\nauthor = {Meneghini, O. and Slendebroek, T. and Lyons, B.C. and McLaughlin, K. and McClenaghan, J. and Stagner, L. and Harvey, J. and Neiser, T.F. and Ghiozzi, A. and Dose, G. and Guterl, J. and Zalzali, A. and Cote, T. and Shi, N. and Weisberg, D. and Smith, S.P. and Grierson, B.A. and Candy, J.},\ndoi = {10.48550/arXiv.2409.05894},\njournal = {arXiv},\ntitle = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}},\nyear = {2024}\n}","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Last update on 2024-10-21T02:41:46.827","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"EditURL = \"tutorial.jl\"","category":"page"},{"location":"tutorial.html#FUSE-Introductory-Tutorial","page":"Tutorial","title":"FUSE Introductory Tutorial","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Download this tutorial from the FuseExamples repository","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Import the necessary packages","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"using Plots # for plotting\nusing FUSE # this will also import IMAS in the current namespace","category":"page"},{"location":"tutorial.html#Starting-from-a-use-case","page":"Tutorial","title":"Starting from a use-case","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE comes with some predefined use-cases, some of which are used for regression testing. Note that some use cases are for non-nuclear experiments and certain Actors like Blankets or BalanceOfPlant will not perform any actions.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.test_cases","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Get initial parameters (ini) and actions (act) for a given use-case","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ini, act = FUSE.case_parameters(:KDEMO);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Modifying ini parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ini.equilibrium.B0 = 7.8\nini.equilibrium.R0 = 6.5;\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Modifying act parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"act.ActorCoreTransport.model = :FluxMatcher;\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Initialize the data dictionary (dd) using the 0D parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"NOTE: init() does not return a self-consistent solution, just a plausible starting point to initialize our simulations!","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd = FUSE.init(ini, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Using checkpoints to save and restore states (we'll use this later)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"chk = FUSE.Checkpoint()\n@checkin chk :init dd ini act","category":"page"},{"location":"tutorial.html#Exploring-the-data-dictionary","page":"Tutorial","title":"Exploring the data dictionary","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE stores data following the IMAS data schema.\nThe root of the data structure is dd, which stands for \"Data Dictionary\".\nMore details are available in the documentation.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Display part of the equilibrium data in dd","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.time_slice[2].boundary","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"this can be done up to a certain depth with print_tree","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(dd.equilibrium.time_slice[2].boundary; maxdepth=1)","category":"page"},{"location":"tutorial.html#Plotting-data-from-dd","page":"Tutorial","title":"Plotting data from dd","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE provides Plots.jl recipes for visualizing data from dd, this means different plots are shown by calling the same plot() function on different items in the data structure. Learn more about Plots.jl here","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"For example plotting the equilibrium...","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.equilibrium)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"...or the core profiles","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Whant to know what arguments can be passed? use help_plot() function","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"help_plot(dd.equilibrium; core_profiles_overlay=true, psi_levels_in=21, psi_levels_out=5, show_secondary_separatrix=true, coordinate=:psi_norm)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"These plots can be composed by calling plot!() instead of plot()","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.equilibrium; color=:gray, cx=true)\nplot!(dd.build; equilibrium=false, pf_active=false)\nplot!(dd.pf_active)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Plotting an array...","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1].pressure_thermal)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"...is different from plotting a field from the IDS (which plots the quantity against its coordinate and with units)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1], :pressure_thermal)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Customizing plot attributes:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1], :pressure_thermal; label=\"\", linewidth=2, color=:red, labelfontsize=25)","category":"page"},{"location":"tutorial.html#Working-with-time-series","page":"Tutorial","title":"Working with time series","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The IMAS data structure supports time-dependent data, and IMAS.jl provides ways to handle time data efficiently.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Each dd has a global_time attribute, and actors operate at such time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Here we see that equilibrium has mulitiple time_slices","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Accessing time-dependent arrays of structures, via integer index","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[2]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"At a given time, by passing the time as a floating point number (in seconds)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[0.0]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"At the global time, leaving the square brackets empty","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Using the @ddtime macro to access and modify time-dependent arrays at dd.global_time:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.vacuum_toroidal_field.b0","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Accessing data at dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"my_b0 = @ddtime(dd.equilibrium.vacuum_toroidal_field.b0)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Writin data at dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@ddtime(dd.equilibrium.vacuum_toroidal_field.b0 = my_b0 + 1)\n\ndd.equilibrium.vacuum_toroidal_field.b0","category":"page"},{"location":"tutorial.html#Expressions-in-dd","page":"Tutorial","title":"Expressions in dd","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Some fields in the data dictionary are expressions (ie. Functions). For example dd.core_profiles.profiles_1d[].pressure is dynamically calculated as the product of thermal densities and temperature with addition of fast ions contributions","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(dd.core_profiles.profiles_1d[1]; maxdepth=1)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"accessing a dynamic expression, automatically evaluates it (in the pressure example, we get an array with data)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.core_profiles.profiles_1d[1].electrons.pressure","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"In addition to evaluating expressions by accessing them, expressions in the tree can be evaluated using IMAS.freeze()","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(IMAS.freeze(dd.core_profiles.profiles_1d[1]); maxdepth=1)","category":"page"},{"location":"tutorial.html#Whole-facility-design","page":"Tutorial","title":"Whole facility design","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Here we restore the :init checkpoint that we had previously stored. Resetting any changes to dd, ini, and act that we did in the meantime.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkout chk :init dd ini act","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Actors in FUSE can be executed by passing two arguments to them: dd and act. Internally, actors can call other actors, creating workflows. For example, the ActorWholeFacility can be used to to get a self-consistent stationary whole facility design. The actors: print statements with their nested output tell us what actors are calling other actors.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorWholeFacility(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Like before we can checkpoint results for later use","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkin chk :awf dd ini act","category":"page"},{"location":"tutorial.html#Running-a-custom-workflow","page":"Tutorial","title":"Running a custom workflow","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's now run a series of actors similar to what ActorWholeFacility does and play around with plotting to get a sense of what each individual actor does.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's start again from after the initialization stage","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkout chk :init dd ini act","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's start by positioning the PF coils, so that we stand a chance to reproduce the desired plasma shape. This will be important to ensure the stability of the ActorStationaryPlasma that we are going to run next.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorPFdesign(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorStationaryPlasma iterates between plasma transport, pedestal, equilibrium and sources to return a self-consistent plasma solution","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"peq = plot(dd.equilibrium; label=\"before\")\npcp = plot(dd.core_profiles; color=:gray, label=\"before\")\nFUSE.ActorStationaryPlasma(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"we can compare equilibrium before and after the self-consistency loop","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot!(peq, dd.equilibrium; label=\"after\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"we can compare core_profiles before and after the self-consistency loop","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot!(pcp, dd.core_profiles; label=\"after\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"here are the sources","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_sources)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"and the flux-matched transport","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_transport)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"HFS sizing actor changes the thickness of the OH and TF layers on the high field side to satisfy current and stresses constraints","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.build)\nFUSE.ActorHFSsizing(dd, act);\nplot!(dd.build; cx=false)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The stresses on the center stack are stored in the solid_mechanics IDS","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.solid_mechanics.center_stack.stress)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"LFS sizing actors change location of the outer TF leg to meet ripple requirements","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.build)\nFUSE.ActorLFSsizing(dd, act);\nplot!(dd.build; cx=false)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"A custom show() method is defined to print the summary of dd.build.layer","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.build.layer","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorHFSsizing and ActorLFSsizing only change the layer's thicknesses, so we then need to trigger a build of the 2D cross-sections after them:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorCXbuild(dd, act);\nplot(dd.build)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Generate passive structures information (for now the vacuum vessel)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorPassiveStructures(dd, act)\nplot(dd.pf_passive)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"We can now give the PF coils their final position given the new build","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorPFdesign(dd, act);\nplot(actor)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"With information about both pfactive and pfpassive we can now evaluate vertical stability","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorVerticalStability(dd, act)\nIMAS.freeze(dd.mhd_linear)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorNeutronics calculates the heat flux on the first wall","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorNeutronics(dd, act);\np = plot(; layout=2, size=(900, 350))\nplot!(p, dd.neutronics.time_slice[].wall_loading, subplot=1)\nplot!(p, FUSE.define_neutrons(dd, 100000)[1], dd.equilibrium.time_slice[]; subplot=1, colorbar_entry=false)\nplot!(p, dd.neutronics.time_slice[].wall_loading; cx=false, subplot=2, ylabel=\"\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorBlanket will change the thickess of the first wall, breeder, shield, and Li6 enrichment to achieve target TBR","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorBlanket(dd, act);\nprint_tree(IMAS.freeze(dd.blanket); maxdepth=5)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorDivertors actor calculates the divertors heat flux","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorDivertors(dd, act);\nprint_tree(IMAS.freeze(dd.divertors); maxdepth=4)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorBalanceOfPlant calculates the optimal cooling flow rates for the heat sources (breeder, divertor, and wall) and get an efficiency for the electricity conversion cycle","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorBalanceOfPlant(dd, act);\nplot(actor)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorCosting will break down the capital and operational costs","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorCosting(dd, act)\nplot(dd.costing)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's checkpoint our results","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkin chk :manual dd ini act","category":"page"},{"location":"tutorial.html#Saving-and-loading-data","page":"Tutorial","title":"Saving and loading data","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"tutorial_temp_dir = tempdir()\nfilename = joinpath(tutorial_temp_dir, \"$(ini.general.casename).json\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"When saving data to be shared outside of FUSE, one can set freeze=true so that all expressions in the dd are evaluated and saved to file.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"IMAS.imas2json(dd, filename; freeze=false, strict=false);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Load from JSON","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd1 = IMAS.json2imas(filename);\nnothing #hide","category":"page"},{"location":"tutorial.html#Comparing-two-IDSs","page":"Tutorial","title":"Comparing two IDSs","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"We can introduce a change in the dd1 and spot it with the diff function","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd1.equilibrium.time_slice[1].time = -100.0\nIMAS.diff(dd.equilibrium, dd1.equilibrium)","category":"page"},{"location":"tutorial.html#Summary","page":"Tutorial","title":"Summary","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Snapshot of dd in 0D quantities (evaluated at dd.global_time)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.extract(dd)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Extract + plots saved to PDF (or printed to screen it filename is omitted)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"filename = joinpath(tutorial_temp_dir, \"$(ini.general.casename).pdf\")\nFUSE.digest(dd)#, filename)","category":"page"}] +[{"location":"cases.html#Use-cases","page":"Use Cases","title":"Use cases","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"CurrentModule = FUSE","category":"page"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"FUSE comes with a set of pre-cookes used cases. The case_parameters(:use_case, ...) method returns the ini and act parameters for that specific use_case. These ini and act can then be further customized before running a FUSE simulation.","category":"page"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"To create your own case and add them to FUSE/cases copy one of the other cases as a template and change the ini/act parameters inside. A handy way of generating the ini code from your_ini that you created in a notebook or elsewhere is to call the function FUSE.case_parameter_creation_from_ini(your_ini) which will return a nicely formatted code snippet.","category":"page"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"tip: Tip!\nClick on the Source button of each use case to see how each is setup","category":"page"},{"location":"cases.html#ARC","page":"Use Cases","title":"ARC","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:ARC}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:ARC}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:ARC; flux_matcher::Bool=false)\n\nCFS/MIT ARC design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#CAT","page":"Use Cases","title":"CAT","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:CAT}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:CAT}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:CAT)\n\nGA Compact Advanced Tokamak design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#D3D","page":"Use Cases","title":"D3D","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:D3D}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:D3D}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:D3D;\n scenario::Union{Symbol,AbstractString}=:default,\n use_scenario_sources::Bool=typeof(scenario)\n\nDIII-D\n\nScenario keyword can be:\n\n:default 133221\n:H_mode a prototypical H_mode\n:L_mode a prototypical L_mode\na user defined string pointing to a ODS on file saved in JSON format\n\nuse_scenario_sources keywods says whether core_sources will be taken from scenario or not\n\n\n\n\n\n","category":"method"},{"location":"cases.html#DTT","page":"Use Cases","title":"DTT","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:DTT}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:DTT}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:DTT)\n\nDTT\n\n\n\n\n\n","category":"method"},{"location":"cases.html#EXCITE","page":"Use Cases","title":"EXCITE","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:EXCITE}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:EXCITE}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(::Type{Val{:EXCITE}})::Tuple{ParametersAllInits,ParametersAllActors}\n\nGA EXCITE design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#FIRST","page":"Use Cases","title":"FIRST","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:FIRST}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:FIRST}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:FIRST)\n\nFormosa Integrated Research Spherical Tokamak\n\n\n\n\n\n","category":"method"},{"location":"cases.html#FPP","page":"Use Cases","title":"FPP","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:FPP}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:FPP}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:FPP; flux_matcher::Bool=false)\n\nGA's FPP design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#HDB5","page":"Use Cases","title":"HDB5","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:HDB5}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:HDB5}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(::Type{Val{:HDB5}}; tokamak::Union{String,Symbol}=:any, case=missing, database_case=missing)\n\nFor description of cases/variables see https://osf.io/593q6/\n\n\n\n\n\n","category":"method"},{"location":"cases.html#ITER","page":"Use Cases","title":"ITER","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:ITER}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:ITER}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(\n :ITER,\n init_from::Symbol,\n boundary_from::Symbol=:auto,\n ne_setting::Symbol=:ne_ped,\n time_dependent::Bool=false)\n\nITER\n\n\n\n\n\n","category":"method"},{"location":"cases.html#KDEMO","page":"Use Cases","title":"KDEMO","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:KDEMO}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:KDEMO}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:KDEMO)\n\n\n\n\n\n","category":"method"},{"location":"cases.html#MANTA","page":"Use Cases","title":"MANTA","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:MANTA}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:MANTA}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:MANTA; flux_matcher::Bool=false)\n\nMANTA (Modular Adjustable Negative-Triangularity ARC)\n\nhttps://arxiv.org/abs/2405.20243\n\nhttps://burningplasma.org/resources/ref/WebSeminars/MANTAUSBPOWebinarPresentation.pdf\n\n\n\n\n\n","category":"method"},{"location":"cases.html#SPARC","page":"Use Cases","title":"SPARC","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:SPARC}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:SPARC}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(:SPARC; flux_matcher::Bool=false)\n\nCFS/MIT SPARC design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#STEP","page":"Use Cases","title":"STEP","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:STEP}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:STEP}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(::Type{Val{:STEP}}; init_from::Symbol=:scalars, pf_from::Symbol=init_from)\n\nUKAEA STEP design\n\n\n\n\n\n","category":"method"},{"location":"cases.html#baby_MANTA","page":"Use Cases","title":"baby_MANTA","text":"","category":"section"},{"location":"cases.html","page":"Use Cases","title":"Use Cases","text":"case_parameters(::Type{Val{:baby_MANTA}})","category":"page"},{"location":"cases.html#FUSE.case_parameters-Tuple{Type{Val{:baby_MANTA}}}","page":"Use Cases","title":"FUSE.case_parameters","text":"case_parameters(::Type{Val{:baby_MANTA}}; flux_matcher::Bool=false)\n\n\n\n\n\n","category":"method"},{"location":"actors.html#Physics-and-Engineering-Actors","page":"List of actors","title":"Physics and Engineering Actors","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"Physics and engineering actors are the fundamental building blocks of FUSE simulations:","category":"page"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"Actors operate exclusively on IMAS.dd data\nActors functionality is controlled via act parameters\nActors can be combined into other actors","category":"page"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"Fidelity hierarchy is enabled by concept of generic Vs specific actors","category":"page"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"Generic actors define physics/component \nSpecific actors implement a specific model for that physics/component\nFor example:\nActorEquilibrium <-- generic\n├─ ActorSolovev <-- specific\n└─ ActorCHEASE <-- specific\nact.[ActorGeneric].model selects specific actor being used\nAll specific actors will expect data and fill the same enties in dd\nIMAS.jl expressions are key to make this work seamlessly\nWhere possible actors should make use of generic actors and not hardcode use of specific actors","category":"page"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":" Pages = [\"actors.md\"]\n Depth = 3","category":"page"},{"location":"actors.html#Balance-plant-(3-actors)","page":"List of actors","title":"Balance plant (3 actors)","text":"","category":"section"},{"location":"actors.html#BalanceOfPlant","page":"List of actors","title":"BalanceOfPlant","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorBalanceOfPlant(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorBalanceOfPlant-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorBalanceOfPlant","text":"ActorBalanceOfPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nBalance of plant actor that estimates the net electrical power output by comparing the balance of plant electrical needs with the electricity generated from the thermal cycle.\n\nnote: Note\n\n\nStores data in dd.balance_of_plant\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorBalanceOfPlant) # hide","category":"page"},{"location":"actors.html#PowerNeeds","page":"List of actors","title":"PowerNeeds","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPowerNeeds(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPowerNeeds-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPowerNeeds","text":"ActorPowerNeeds(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nPower needs actor that calculates the needed power to operate the plant\n\nmodel = :thermal_power_fraction simply assumes that the power to balance a plant is a fraction of the gross electrical power generated by the thermal cycle.\nmodel = :EU_DEMO subdivides the power plant electrical needs to [:cryostat, :tritium_handling, :pumping] using EU-DEMO numbers.\nmodel = :FUSE subdivides power plant needs into subsystems and calculates their power needs.\n\nnote: Note\n\n\nStores data in dd.balance_of_plant.power_electric_plant_operation\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPowerNeeds) # hide","category":"page"},{"location":"actors.html#ThermalPlant","page":"List of actors","title":"ThermalPlant","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorThermalPlant(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorThermalPlant-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorThermalPlant","text":"ActorThermalPlant(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nnote: Note\nStores data in dd.balance_of_plant\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorThermalPlant) # hide","category":"page"},{"location":"actors.html#Build-(5-actors)","page":"List of actors","title":"Build (5 actors)","text":"","category":"section"},{"location":"actors.html#CXbuild","page":"List of actors","title":"CXbuild","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCXbuild(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCXbuild-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCXbuild","text":"ActorCXbuild(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nGenerates the 2D cross section of the tokamak build\n\nnote: Note\nManipulates data in dd.build\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCXbuild) # hide","category":"page"},{"location":"actors.html#HFSsizing","page":"List of actors","title":"HFSsizing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorHFSsizing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorHFSsizing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorHFSsizing","text":"ActorHFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nActor that resizes the High Field Side of the tokamak radial build\n\ntakes into account the OH maximum allowed superconductor current/Field\ntakes into account the stresses on the center stack\n\nnote: Note\nManipulates radial build information in dd.build.layer\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorHFSsizing) # hide","category":"page"},{"location":"actors.html#FluxSwing","page":"List of actors","title":"FluxSwing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxSwing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxSwing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxSwing","text":"ActorFluxSwing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nDepending on operate_oh_at_j_crit\n\ntrue => Evaluate the OH current limits, and evaluate flattop duration from that.\nfalse => Evaluate what are the currents needed for a given flattop duration. This may or may not exceed the OH current limits.\n\nOH flux consumption based on:\n\nrampup estimate based on Ejima coefficient\nflattop consumption\nvertical field from PF coils\n\nnote: Note\nStores data in dd.build.flux_swing, dd.build.tf, and dd.build.oh\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxSwing) # hide","category":"page"},{"location":"actors.html#LFSsizing","page":"List of actors","title":"LFSsizing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorLFSsizing(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorLFSsizing-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorLFSsizing","text":"ActorLFSsizing(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nActor that resizes the Low Field Side of the tokamak radial build\n\nPlaces TF outer leg at radius required to meet the dd.build.tf.ripple requirement\nOther low-field side layers are scaled proportionally\n\nnote: Note\n\n\nManipulates radial build information in dd.build.layer\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorLFSsizing) # hide","category":"page"},{"location":"actors.html#Stresses","page":"List of actors","title":"Stresses","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStresses(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStresses-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStresses","text":"ActorStresses(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates mechanical stresses on the center stack\n\nnote: Note\nStores data in dd.solid_mechanics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStresses) # hide","category":"page"},{"location":"actors.html#Compound-(3-actors)","page":"List of actors","title":"Compound (3 actors)","text":"","category":"section"},{"location":"actors.html#DynamicPlasma","page":"List of actors","title":"DynamicPlasma","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorDynamicPlasma(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorDynamicPlasma-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorDynamicPlasma","text":"ActorDynamicPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound evolves plasma in time\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorDynamicPlasma) # hide","category":"page"},{"location":"actors.html#StationaryPlasma","page":"List of actors","title":"StationaryPlasma","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStationaryPlasma(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStationaryPlasma-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStationaryPlasma","text":"ActorStationaryPlasma(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound actor that runs the following actors in succesion:\n\nActorCurrent\nActorHCD\nActorCoreTransport\nActorEquilibrium\n\nnote: Note\nStores data in dd.equilibrium, dd.core_profiles, dd.core_sources, dd.core_transport\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStationaryPlasma) # hide","category":"page"},{"location":"actors.html#WholeFacility","page":"List of actors","title":"WholeFacility","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorWholeFacility(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorWholeFacility-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorWholeFacility","text":"ActorWholeFacility(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompound actor that runs all the physics, engineering and costing actors needed to model the whole plant:\n\nActorStationaryPlasma\nActorStabilityLimits\nActorHFSsizing\nActorLFSsizing\nActorCXbuild\nActorFluxSwing\nActorStresses\nActorPFdesign\nActorPFactive\nActorPassiveStructures\nActorVerticalStability\nActorNeutronics\nActorBlanket\nActorDivertors\nActorBalanceOfPlant\nActorCosting\n\nnote: Note\nStores data in dd\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorWholeFacility) # hide","category":"page"},{"location":"actors.html#Costing-(3-actors)","page":"List of actors","title":"Costing (3 actors)","text":"","category":"section"},{"location":"actors.html#Costing","page":"List of actors","title":"Costing","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCosting(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCosting-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCosting","text":"ActorCosting(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the cost of building, operating, and recommission the fusion power plant.\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCosting) # hide","category":"page"},{"location":"actors.html#CostingARIES","page":"List of actors","title":"CostingARIES","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCostingARIES(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCostingARIES-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCostingARIES","text":"ActorCostingARIES(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates costing based on ARIES cost account documentation https://cer.ucsd.edu/_files/publications/UCSD-CER-13-01.pdf\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCostingARIES) # hide","category":"page"},{"location":"actors.html#CostingSheffield","page":"List of actors","title":"CostingSheffield","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCostingSheffield(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCostingSheffield-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCostingSheffield","text":"ActorCostingSheffield(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates costing based on Sheffield and Milora, FS&T 70 (2016)\n\nnote: Note\nStores data in dd.costing\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCostingSheffield) # hide","category":"page"},{"location":"actors.html#Current-(3-actors)","page":"List of actors","title":"Current (3 actors)","text":"","category":"section"},{"location":"actors.html#Current","page":"List of actors","title":"Current","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCurrent(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCurrent-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCurrent","text":"ActorCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple ohmic current evolution actors\n\nSets the j_ohmic, j_tor, j_total under dd.core_profiles.profiles_1d[]\nSets j_parallel in dd.equilibrium.time_slice[].profiles_1d\nUpdates bootstrap and ohmic parallel current and heating sources in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCurrent) # hide","category":"page"},{"location":"actors.html#QED","page":"List of actors","title":"QED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorQED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorQED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorQED","text":"ActorQED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvolves the plasma current using the QED current diffusion solver.\n\nnote: Note\nThis actor operates at \"dd.global_time\", any time advance must be done outside of the actorIMAS.new_timeslice!(dd, dd.global_time + Δt)\ndd.global_time += Δt\nActorQED(dd, act)\n\nnote: Note\nStores data in dd.core_profiles.profiles_1d[].j_ohmic\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorQED) # hide","category":"page"},{"location":"actors.html#SteadyStateCurrent","page":"List of actors","title":"SteadyStateCurrent","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSteadyStateCurrent(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSteadyStateCurrent-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSteadyStateCurrent","text":"ActorSteadyStateCurrent(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvolves the ohmic current to steady state using the conductivity from dd.core_profiles\n\nnote: Note\nStores data in dd.core_profiles.profiles_1d[].j_ohmic\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSteadyStateCurrent) # hide","category":"page"},{"location":"actors.html#Divertors-(1-actors)","page":"List of actors","title":"Divertors (1 actors)","text":"","category":"section"},{"location":"actors.html#Divertors","page":"List of actors","title":"Divertors","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorDivertors(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorDivertors-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorDivertors","text":"ActorDivertors(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates divertor loading and deposited power\n\nnote: Note\nStores data in dd.divertors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorDivertors) # hide","category":"page"},{"location":"actors.html#Equilibrium-(4-actors)","page":"List of actors","title":"Equilibrium (4 actors)","text":"","category":"section"},{"location":"actors.html#Equilibrium","page":"List of actors","title":"Equilibrium","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEquilibrium(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEquilibrium-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEquilibrium","text":"ActorEquilibrium(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple equilibrium actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEquilibrium) # hide","category":"page"},{"location":"actors.html#CHEASE","page":"List of actors","title":"CHEASE","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCHEASE(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCHEASE-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCHEASE","text":"ActorCHEASE(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns the Fixed boundary equilibrium solver CHEASE\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCHEASE) # hide","category":"page"},{"location":"actors.html#Solovev","page":"List of actors","title":"Solovev","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSolovev(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSolovev-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSolovev","text":"ActorSolovev(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nSolovev equilibrium actor, based on: “One size fits all” analytic solutions to the Grad–Shafranov equation Phys. Plasmas 17, 032502 (2010); https://doi.org/10.1063/1.3328818\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSolovev) # hide","category":"page"},{"location":"actors.html#TEQUILA","page":"List of actors","title":"TEQUILA","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorTEQUILA(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorTEQUILA-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorTEQUILA","text":"ActorTEQUILA(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns the Fixed boundary equilibrium solver TEQUILA\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorTEQUILA) # hide","category":"page"},{"location":"actors.html#Hcd-(5-actors)","page":"List of actors","title":"Hcd (5 actors)","text":"","category":"section"},{"location":"actors.html#HCD","page":"List of actors","title":"HCD","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorHCD(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorHCD-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorHCD","text":"ActorHCD(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run HCD actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorHCD) # hide","category":"page"},{"location":"actors.html#SimpleEC","page":"List of actors","title":"SimpleEC","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleEC(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleEC-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleEC","text":"ActorSimpleEC(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the EC electron energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.ec_launchers, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleEC) # hide","category":"page"},{"location":"actors.html#SimpleIC","page":"List of actors","title":"SimpleIC","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleIC(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleIC-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleIC","text":"ActorSimpleIC(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the ion-cyclotron electron/ion energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.ic_antennas, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleIC) # hide","category":"page"},{"location":"actors.html#SimpleLH","page":"List of actors","title":"SimpleLH","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimpleLH(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimpleLH-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimpleLH","text":"ActorSimpleLH(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the Lower-hybrid electron energy deposition and current drive as a gaussian.\n\nNOTE: Current drive efficiency from GASC, based on \"G. Tonon 'Current Drive Efficiency Requirements for an Attractive Steady-State Reactor'\"\n\nnote: Note\nReads data in dd.lh_antennas, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimpleLH) # hide","category":"page"},{"location":"actors.html#SimplePellet","page":"List of actors","title":"SimplePellet","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorSimplePellet(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorSimplePellet-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorSimplePellet","text":"ActorSimplePellet(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the Pellet particle deposition\n\nnote: Note\nReads data in dd.pellet_launchers, dd.pulse_schedule and stores data in dd.core_sources\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorSimplePellet) # hide","category":"page"},{"location":"actors.html#Nuclear-(2-actors)","page":"List of actors","title":"Nuclear (2 actors)","text":"","category":"section"},{"location":"actors.html#Blanket","page":"List of actors","title":"Blanket","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorBlanket(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorBlanket-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorBlanket","text":"ActorBlanket(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates blankets tritium breeding ratio (TBR), heat deposition, and neutron leakage\n\nnote: Note\nStores data in dd.blanket\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorBlanket) # hide","category":"page"},{"location":"actors.html#Neutronics","page":"List of actors","title":"Neutronics","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorNeutronics(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorNeutronics-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorNeutronics","text":"ActorNeutronics(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEstimates the neutron wall loading\n\nnote: Note\nStores data in dd.neutronics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorNeutronics) # hide","category":"page"},{"location":"actors.html#Pedestal-(3-actors)","page":"List of actors","title":"Pedestal (3 actors)","text":"","category":"section"},{"location":"actors.html#Pedestal","page":"List of actors","title":"Pedestal","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPedestal(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPedestal-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPedestal","text":"ActorPedestal(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the pedestal boundary condition (height and width)\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPedestal) # hide","category":"page"},{"location":"actors.html#EPED","page":"List of actors","title":"EPED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEPED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEPED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEPED","text":"ActorEPED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the pedestal boundary condition (height and width)\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEPED) # hide","category":"page"},{"location":"actors.html#WPED","page":"List of actors","title":"WPED","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorWPED(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorWPED-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorWPED","text":"ActorWPED(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nFinds the temperature profile at the edge to match the pedtocorefraction of stored energy set in par.pedtocorefraction\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorWPED) # hide","category":"page"},{"location":"actors.html#Pf-(3-actors)","page":"List of actors","title":"Pf (3 actors)","text":"","category":"section"},{"location":"actors.html#PFdesign","page":"List of actors","title":"PFdesign","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPFdesign(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPFdesign-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPFdesign","text":"ActorPFdesign(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nOptimize PF coil locations to achieve desired equilibrium\n\nnote: Note\nManupulates data in dd.pf_active\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPFdesign) # hide","category":"page"},{"location":"actors.html#PFactive","page":"List of actors","title":"PFactive","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPFactive(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPFactive-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPFactive","text":"ActorPFactive(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nFinds the optimal coil currents to match the equilibrium boundary shape\n\nnote: Note\nManupulates data in dd.pf_active\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPFactive) # hide","category":"page"},{"location":"actors.html#PassiveStructures","page":"List of actors","title":"PassiveStructures","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorPassiveStructures(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorPassiveStructures-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorPassiveStructures","text":"ActorPassiveStructures(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nPopulates pf_passive structures\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorPassiveStructures) # hide","category":"page"},{"location":"actors.html#Stability-(2-actors)","page":"List of actors","title":"Stability (2 actors)","text":"","category":"section"},{"location":"actors.html#StabilityLimits","page":"List of actors","title":"StabilityLimits","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorStabilityLimits(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorStabilityLimits-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorStabilityLimits","text":"ActorStabilityLimits(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nRuns all the limit actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorStabilityLimits) # hide","category":"page"},{"location":"actors.html#VerticalStability","page":"List of actors","title":"VerticalStability","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorVerticalStability(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorVerticalStability-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorVerticalStability","text":"ActorVerticalStability(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nCompute vertical stability metrics\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorVerticalStability) # hide","category":"page"},{"location":"actors.html#Transport-(7-actors)","page":"List of actors","title":"Transport (7 actors)","text":"","category":"section"},{"location":"actors.html#CoreTransport","page":"List of actors","title":"CoreTransport","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCoreTransport(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCoreTransport-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCoreTransport","text":"ActorCoreTransport(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple core transport actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCoreTransport) # hide","category":"page"},{"location":"actors.html#EPEDprofiles","page":"List of actors","title":"EPEDprofiles","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorEPEDprofiles(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorEPEDprofiles-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorEPEDprofiles","text":"ActorEPEDprofiles(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nUpdates pedestal height and width and blends with core profiles that are defined by shaping factors.\n\nDoes not change on-axis values of plasma profiles.\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorEPEDprofiles) # hide","category":"page"},{"location":"actors.html#FluxCalculator","page":"List of actors","title":"FluxCalculator","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxCalculator(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxCalculator-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxCalculator","text":"ActorFluxCalculator(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nProvides a common interface to run multiple transport model actors\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxCalculator) # hide","category":"page"},{"location":"actors.html#FluxMatcher","page":"List of actors","title":"FluxMatcher","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorFluxMatcher(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorFluxMatcher-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorFluxMatcher","text":"ActorFluxMatcher(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvalutes the transport fluxes and source fluxes and minimizes the flux_match error\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorFluxMatcher) # hide","category":"page"},{"location":"actors.html#Neoclassical","page":"List of actors","title":"Neoclassical","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorNeoclassical(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorNeoclassical-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorNeoclassical","text":"ActorNeoclassical(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the neoclassical transport fluxes\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorNeoclassical) # hide","category":"page"},{"location":"actors.html#QLGYRO","page":"List of actors","title":"QLGYRO","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorQLGYRO(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorQLGYRO-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorQLGYRO","text":"ActorQLGYRO(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the QLGYRO predicted turbulence\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorQLGYRO) # hide","category":"page"},{"location":"actors.html#TGLF","page":"List of actors","title":"TGLF","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorTGLF(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorTGLF-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorTGLF","text":"ActorTGLF(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nEvaluates the TGLF predicted turbulence\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorTGLF) # hide","category":"page"},{"location":"actors.html#Wall-loading-(2-actors)","page":"List of actors","title":"Wall loading (2 actors)","text":"","category":"section"},{"location":"actors.html#CoreRadHeatFlux","page":"List of actors","title":"CoreRadHeatFlux","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorCoreRadHeatFlux(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorCoreRadHeatFlux-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorCoreRadHeatFlux","text":"ActorCoreRadHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nComputes the heat flux on the wall due to the core radiation\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorCoreRadHeatFlux) # hide","category":"page"},{"location":"actors.html#ParticleHeatFlux","page":"List of actors","title":"ParticleHeatFlux","text":"","category":"section"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"FUSE.ActorParticleHeatFlux(dd::IMAS.dd, act::FUSE.ParametersAllActors; kw...)","category":"page"},{"location":"actors.html#FUSE.ActorParticleHeatFlux-Tuple{IMASdd.dd, FUSE.ParametersAllActors}","page":"List of actors","title":"FUSE.ActorParticleHeatFlux","text":"ActorParticleHeatFlux(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nComputes the heat flux on the wall due to the charged particles\n\n\n\n\n\n","category":"method"},{"location":"actors.html","page":"List of actors","title":"List of actors","text":"import FUSE # hide\nact = FUSE.ParametersActors() # hide\ngetfield(FUSE.ParametersActors(), :ActorParticleHeatFlux) # hide","category":"page"},{"location":"develop.html#Contributing","page":"Contributing","title":"Contributing","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"FUSE is a collaborative project that welcomes community contributions!","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The master branch of ProjectTorreyPines repositories is write-protected. This means that even with write permissions to the repository, you'll not be able to push to master directly. Instead, we handle updates – be it new features or bug fixes – through branches and Pull Requests (PRs).","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"A crucial part of our PR process is code review. It is where your peers get to weigh in and ensure everything is up to standard before merging. When you create a PR, think about who on the team has the right expertise for the code you're working on, and assign them as reviewers. Their insights will not only help in maintaining code quality but also in catching any potential issues early. It is all about teamwork and making sure our code is the best it can be!","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nWhen working on a new feature that involves changes to FUSE and other ProjectTorreyPines repositories, you'll want to use the same branch name across these repositories. For example, if you're working on a branch named my_new_feature in both FUSE and IMAS, regression testing will be performed using the my_new_feature branches for FUSE and IMAS, along with the master branch of the other ProjectTorreyPines repositories.","category":"page"},{"location":"develop.html#Add/modify-entries-in-dd","page":"Contributing","title":"Add/modify entries in dd","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The dd data structure is defined under the IMASdd.jl package. See the documentation there to how add/modify entries in dd.","category":"page"},{"location":"develop.html#Write-IMAS-physics-functions","page":"Contributing","title":"Write IMAS physics functions","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"IMAS physics and engineering functions are structured in IMAS.jl under IMAS/src/physics. These functions use or modify the datastructure (dd) in some way and are used to calculate certain quantities or fill the data structure.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Let's say we want to create a function that calculates the DT fusion and then fill core_sources with the alpha heating from that source. Here is an example of writing it in a good way:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function DT_fusion_source!(dd::IMAS.dd)\n return DT_fusion_source!(dd.core_sources, dd.core_profiles)\nend\n\n\"\"\"\n DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles)\n\nCalculates DT fusion heating with an estimation of the alpha slowing down to the ions and electrons, modifies dd.core_sources\n\"\"\"\nfunction DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles)\n # // actual implementation here //\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"convention: Convention\nThe documentation string is added to the specialized function DT_fusion_source!(cs::IMAS.core_sources, cp::IMAS.core_profiles) and the dispatch function DT_fusion_source!(dd::IMAS.dd) is added on top of the function","category":"page"},{"location":"develop.html#Add/modify-entries-in-ini-and-act","page":"Contributing","title":"Add/modify entries in ini and act","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The functinoality of the ini and act parameters is implemented in the SimulationParameters.jl package.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The ini parameters are all defined in the FUSE/src/parameters_init.jl file. Add/edit entries there.\nThe act parameters of each actor are defined where that actor is defined. Add/edit entries there.","category":"page"},{"location":"develop.html#Write-a-new-actor","page":"Contributing","title":"Write a new actor","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Actors are grouped into two main abstract types:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"abstract type CompoundAbstractActor{D,P} <: AbstractActor{D,P} end\nabstract type SingleAbstractActor{D,P} <: AbstractActor{D,P} end","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"CompoundAbstractActors are for actors that compound multiple actors underneath and are initalized with ActorNAME(dd, par, act) while SingleAbstractActors are single actors initalized with ActorNAME(dd, par)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The definition of each FUSE actor follows a well defined pattern. DO NOT deviate from this pattern. This is important to ensure modularity and compostability of the actors.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"# Definition of the `act` parameters relevant to the actor\nBase.@kwdef mutable struct FUSEparameters__ActorNAME{T<:Real} <: ParametersActor{T}\n _parent::WeakRef = WeakRef(nothing)\n _name::Symbol = :not_set\n length::Entry{T} = Entry(T, \"m\", \"Some decription\") # it's ok not to have a default, it forces users to think about what a parameter should be\n verbose::Entry{Bool} = Entry(Bool, \"\", \"Some other decription\"; default=true)\n switch::Switch{Symbol} = Switch(Symbol, [:option_a, :option_b], \"\", \"user can only select one of these\"; default=:option_a)\nend\n\n# Defintion of the actor structure\n# NOTE: To be valid all actors must have `dd::IMAS.dd` and `par::FUSEparameters__ActorNAME`\nmutable struct ActorNAME <: ???AbstractActor\n dd::IMAS.dd\n par::FUSEparameters__ActorNAME # Actors must carry with them the parameters they are run with\n something_else::??? # Some actors may want to carry something else with them\n # Inner constructor for the actor starting from `dd` and `par` (we generally refer to `par` as `act.ActorNAME`)\n # NOTE: Computation should not happen here since in workflows it is normal to instantiate\n # an actor once `ActorNAME(dd, act.ActorNAME)` and then call `finalize(step(actor))` several times as needed.\n function ActorNAME(dd::IMAS.dd, par::FUSEparameters__ActorNAME; kw...)\n logging_actor_init(ActorNAME)\n par = par(kw...)\n return new(dd, par, something_else)\n end\nend\n\n# Constructor with with `dd` and `act` as arguments will actually run the actor!\n# That's how users will mostly run this actor.\n# This does not change, and it's always the same for all actors\n\"\"\"\n ActorNAME(dd::IMAS.dd, act::ParametersAllActors; kw...)\n\nWhat does this actor do...\n\"\"\"\nfunction ActorNAME(dd::IMAS.dd, act::ParametersAllActors; kw...)\n par = act.ActorNAME(kw...) # this makes a local copy of `act.ActorNAME` and overrides it with keywords that the user may have passed\n actor = ActorNAME(dd, par) # instantiate the actor (see function below)\n step(actor) # run the actor\n finalize(actor) # finalize\n return actor\nend\n\n# define `_step` function for this actor (this is where most of the action occurs)\n# note the leading underscore (use the `_step()` and not `step()` for the FUSE logging system to work with your actor)\n# `_step()` should not take any argument besides the actor itself\nfunction _step(actor::ActorNAME)\n ...\n return actor # _step() should always return the actor\nend\n\n# define `_finalize` function for this actor (this is where typically data gets written in `dd` if that does happen already at the `step`)\n# note the leading underscore (use the `_finalize()` and not `finalize()` for the FUSE logging system to work with your actor)\n# `_finalize()` should not take any argument besides the actor itself\nfunction _finalize(actor::ActorNAME)\n ...\n return actor # _finalize() should always return the actor\nend","category":"page"},{"location":"develop.html#Add-a-new-material","page":"Contributing","title":"Add a new material","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Material properties for supported fusion-relevant materials are stored in the FusionMaterials.jl package, specifically in FusionMaterials/src/materials.jl. Properties of each material can be accessed by calling the Material function with the material name as a symbol passed as the function argument. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To add a new material whose properties can be accessed in FUSE, first add a function to materials.jl called Material with the function argument being your material's name. In the body of the function, assign the material's name (as a string, all lowercase, and with any spaces filled by underscores), type (as a list containing each possible IMAS BuildLayerType the material could be assigned to), density (in kg/m^3) and unit cost (in US dollars per kilogram). Include a comment providing a link to the source from which the unit cost was taken. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Below is an example of a complete Material function for a non-superconductor material (more about superconductor materials below): ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function Material(::Type{Val{:graphite}};)\n\tmat = Material()\n\tmat.name = \"graphite\" # string with no spaces\n\tmat.type = [IMAS._wall_] # list of allowable layer types for this material\n\tmat.density = 1.7e3 # in kg/m^3\n\tmat.unit_cost = 1.3 # in US$/kg, include source as a comment # source: https://businessanalytiq.com/procurementanalytics/index/graphite-price-index/\n\treturn mat\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"If the material is a superconductor that is meant to be assigned to magnet-type layers, additional characteristics need to be defined. First, add the relevant critical current density scaling for the chosen superconductor material as a function in FusionMaterials/src/jcrit.jl. Then, assign the technology parameters for the material (temperature, steel fraction, void fraction, and ratio of superconductor to copper) to their respective fields in coiltech within the coiltechnology function in FUSE/src/technology.jl. Finally, call the critical current density scaling function within the newly written Material function in materials.jl and assign the output critical current density and critical magnetic field to the material object. The coil_tech object should be passed as an argument to the Material function, along with the external B field, and used to calculate the critical current density and critical magnetic field. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Below is an example of a complete superconductor Material function: ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"function Material(::Type{Val{:rebco}}; coil_tech::Union{Missing, IMAS.build__pf_active__technology, IMAS.build__oh__technology, IMAS.build__tf__technology} = missing, Bext::Union{Real, Missing} = missing)\n\tmat = Material()\n\tmat.name = \"rebco\"\n\tmat.type = [IMAS._tf_, IMAS._oh_]\n\tmat.density = 6.3\n\tmat.unit_cost = 7000\n\n\tif !ismissing(coil_tech)\n\t\tJcrit_SC, Bext_Bcrit_ratio = ReBCO_Jcrit(Bext, coil_tech.thermal_strain + coil_tech.JxB_strain, coil_tech.temperature) # A/m^2\n\t\tfc = fraction_conductor(coil_tech)\n\t\tmat.critical_current_density = Jcrit_SC * fc\n\t\tmat.critical_magnetic_field = Bext / Bext_Bcrit_ratio\n\tend\n\n\treturn mat\nend","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The function ReBCO_Jcrit is the critical current density function for this material. ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"You can then access the parameters of your material by calling the function you've created. For example, access the material's density anywhere in FUSE by calling: ","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"my_mat_density = Material(:my_mat).density","category":"page"},{"location":"develop.html#Profiling-and-writing-fast-Julia-code","page":"Contributing","title":"Profiling and writing fast Julia code","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"First let's do some profiling to identify problemetic functions:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Run FUSE from the VScode Julia REPL ( and then Julia: Start REPL)\nusing FUSE\nFUSE.logging(Logging.Info; actors=Logging.Info);\nini, act = FUSE.case_parameters(:FPP; version=:v1_demount, init_from=:scalars, STEP=true);\ndd = IMAS.dd()\nFUSE.init(dd, ini, act)\nFUSE.ActorWholeFacility(dd, act); # call this once to precompile\nnote: Note\n\nAlternatively one can create a profile.jl file in the FUSE/playground folder, write Julia code in that file, select the code to execute and run it with .\nUse @time to monitor execution time and allocations\nFor functions that return very quickly one can use BenchmarkTooks.@benchmark\nGraphical profiling of the execution time is a powerful way to understand where time is spent\n@profview FUSE.ActorWholeFacility(dd, act);\nwhere FUSE.ActorWholeFacility(dd, act); can really be any function that we care about\nLook at allocations\n@profview_allocs FUSE.ActorWholeFacility(dd, act);\nWe can decide how finely to comb for bottlenecks by setting sample_rate in @profview and @profview_allocs:\n@profview_allocs f(args...) [sample_rate=0.0001] [C=false]","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo move forward we have to understand how to write performant Julia code.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Let's now investigate where the issue is with the function that we have identified. For this we have several tools at our disposal:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"@code_warntype: static analyzer built-in with Julia\nonly looks at types that are inferred at runtime\nreports types only for the target function\n@code_warntype function()\nJET: static analyzer integrated with VScode\ncan detect different possible issues, including types inferred at runtime\nJET goes deep into functions\nJET.@report_opt function() reports dynamic dispatch\nJET.@report_call function() reports type errors\nJET.@report_call target_modules=(FUSE,IMAS,IMAS.IMASdd, ) FUSE.ActorNeutronics(dd,act);\nCthulhu: interactive static analyzer\nCthulhu.@descend function()","category":"page"},{"location":"develop.html#Build-the-documentation","page":"Contributing","title":"Build the documentation","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To build the documentation, in the FUSE/docs folder, start Julia then:\n] activate .\ninclude(\"make.jl\")\n!!! tip Interactive documentation build One can call include(\"make.jl\") over and over within the same Julia session to avoid dealing with startup time.\nCheck page by opening FUSE/docs/build/index.html page in web-browser.\nThe online documentation is built after each commit to master via GitHub actions.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nDocumentation files (PDF, DOC, XLS, PPT, ...) can be committed and pushed to the FUSE_extra_files repository, and then linked directly from within the FUSE documentation, like this:[video recording of the first FUSE tutorial](https://github.com/ProjectTorreyPines/FUSE_extra_files/raw/master/FUSE_tutorial_1_6Jul22.mp4)","category":"page"},{"location":"develop.html#Add/modify-examples","page":"Contributing","title":"Add/modify examples","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"The FuseExamples repository contains jupyter notebook that showcase some possible uses of FUSE.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nWhen committing changes to in a jupyter notebook, make sure that all the output cells are cleared! This is important to keep the size of the repository in check.","category":"page"},{"location":"develop.html#Use-Revise.jl","page":"Contributing","title":"Use Revise.jl","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Install Revise.jl to modify code and use the changes without restarting Julia. We recommend adding import Revise to your ~/.julia/config/startup.jl to automatically import Revise at the beginning of all Julia sessions. This can be done by running:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"fusebot install_revise","category":"page"},{"location":"develop.html#Develop-in-VScode","page":"Contributing","title":"Develop in VScode","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"VScode is an excellent development environment for Julia.","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"FUSE uses the following VScode settings for formatting the Julia code:","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"{\n \"files.autoSave\": \"onFocusChange\",\n \"workbench.tree.indent\": 24,\n \"editor.insertSpaces\": true,\n \"editor.tabSize\": 4,\n \"editor.detectIndentation\": false,\n \"[julia]\": {\n \"editor.defaultFormatter\": \"julialang.language-julia\"\n },\n \"juliaFormatter.margin\": 160,\n \"juliaFormatter.alwaysForIn\": true,\n \"juliaFormatter.annotateUntypedFieldsWithAny\": false,\n \"juliaFormatter.whitespaceInKwargs\": false,\n \"juliaFormatter.overwriteFlags\": true,\n \"juliaFormatter.alwaysUseReturn\": true,\n}","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo add these settings to VScode add these lines to: + + p -> Preferences: Open User Settings (JSON)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nTo format Julia you will need to install Julia Language Support under the extensions tab ( + + x)","category":"page"},{"location":"develop.html#Track-Julia-precompilation","page":"Contributing","title":"Track Julia precompilation","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"To see what is precompiled at runtime, you can add a Julia kernel with the trace-compile option to Jupyter","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"import IJulia\nIJulia.installkernel(\"Julia tracecompile\", \"--trace-compile=stderr\")","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Then select the Julia tracecompile in jupyter-lab","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"note: Note\nIf you want to remove jupyter kernels you don't use anymore you can list them first with jupyter kernelspec list and remove via jupyter kernelspec remove ","category":"page"},{"location":"develop.html#Run-Julia-within-a-Python-environment","page":"Contributing","title":"Run Julia within a Python environment","text":"","category":"section"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"This can be particularly useful for benchmarking FUSE physics against existing Python routines (eg. in OMFIT)","category":"page"},{"location":"develop.html","page":"Contributing","title":"Contributing","text":"Install PyCall in your Julia environment:\nexport PYTHON=\"\" # Sometimes one needs to empty the PYTHON environmental variable to install PyCall\njulia -e 'using Pkg; Pkg.add(\"PyCall\"); Pkg.build(\"PyCall\")'\nnote: Note\nPython and Julia must be compiled for the same architecture. For example, to install Julia x64 in a Apple Silicon MACs:juliaup add release~x64\nexport PYTHON=\"\"\njulia +release~x64 -e 'using Pkg; Pkg.add(\"PyCall\"); Pkg.build(\"PyCall\")'You can make this verison your default one withjuliaup default release~x64\nUse pip to install the package PyJulia — remember to use the same Python passed to ENV[\"PYTHON\"]:\npython3 –m pip install julia\nConfigure the communication between Julia and Python by running the following in the Python interpreter:\nimport julia\njulia.install()\nnote: Note\nIf you have more than one Julia version on our system, we could specify it with an argument:julia.install(julia=\"/Users/meneghini/.julia/juliaup/julia-1.8.5+0.x64.apple.darwin14/bin/julia\")\nTest the installation running the following in the Python interpreter run:\nfrom julia import Main\nMain.eval('[x^2 for x in 0:4]')\nNow, try something more useful:\nfrom julia.api import Julia\nJulia(compiled_modules=False)\ndef S(string): # from Python str to Julia Symbol\n return Main.eval(f\"PyCall.pyjlwrap_new({string})\")\n\nfrom julia import Main, IMAS, FUSE, Logging\nFUSE.logging(Logging.Info, actors=Logging.Debug);\n\nini, act = FUSE.case_parameters(S(\":FPP\"), version=S(\":v1_demount\"), init_from=S(\":scalars\"), STEP=True);\ndd = FUSE.init(ini, act);\n\neqt=dd.equilibrium.time_slice[-1]\ncp1d=dd.core_profiles.profiles_1d[-1]\njFUSE = IMAS.Sauter_neo2021_bootstrap(eqt, cp1d, neo_2021=True)","category":"page"},{"location":"install.html#Setup-the-FUSE-environment","page":"Install FUSE","title":"Setup the FUSE environment","text":"","category":"section"},{"location":"install.html#Julia-installation","page":"Install FUSE","title":"Julia installation","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"We highly recommend using the Juliaup manager to install Julia","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Mac & Linux: curl -fsSL https://install.julialang.org | sh\nWindows: winget install julia -s msstore","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Once installed, restart your termninal to pick-up the julia executable.","category":"page"},{"location":"install.html#FUSE-installation","page":"Install FUSE","title":"FUSE installation","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"FUSE and related packages are registered at the FuseRegistry. For installation start your Julia interpreter by typing julia at the terminal, then:","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Add the FuseRegistry and the FUSE package as you would for any other julia package (for a fresh install this can take 20+ mins):\nusing Pkg\nPkg.Registry.add(RegistrySpec(url=\"https://github.com/ProjectTorreyPines/FuseRegistry.jl.git\"))\nPkg.Registry.add(\"General\")\nPkg.add(\"FUSE\")\nNow you should be able to import the FUSE package:\nusing FUSE\nInstall the fusebot utility to simplify install/updates later on. Now fusebot should be a command that you can type anywhere from the terminal.\nFUSE.install_fusebot()\nRun the regression tests (optional, this can take 1h+)\njulia ] test FUSE\nExit julia and clone FUSE examples in the current working directory. To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.\nfusebot install_examples","category":"page"},{"location":"install.html#Keeping-FUSE-up-to-date","page":"Install FUSE","title":"Keeping FUSE up-to-date","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"Get notified of new FUSE releases by \"watching\" the FUSE repo on GitHub\nFUSE is updated like any other Julia package:\njulia ] up","category":"page"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"tip: Tip\nBecome familiar with how managing Julia packages works.","category":"page"},{"location":"install.html#Install-Jupyter-Lab-and-add-the-Julia-kernel-to-it","page":"Install FUSE","title":"Install Jupyter-Lab and add the Julia kernel to it","text":"","category":"section"},{"location":"install.html","page":"Install FUSE","title":"Install FUSE","text":"You will need to install jupyter-lab if that's not already available on your system \nInstall the IJulia package by running:\nfusebot install_IJulia\nnote: Note\nRun fusebot install_IJulia every time a new julia version is installed.This will setup the single- and multi-thread julia kernels in Jupyter.The number of threads of the multi-threaded julia kernels can be set via the JULIA_NUM_THREADS environmental variable.\nStart a new Jupyter-lab session (this should open a web-browser page with Jupyter running)\njupyter-lab\nNow you can browse the examples in the FuseExamples folder that you have cloned, and take a tour of the example Jupyter notebooks there.","category":"page"},{"location":"act.html#act-Parameters","page":"act parameters","title":"act Parameters","text":"","category":"section"},{"location":"act.html","page":"act parameters","title":"act parameters","text":"CurrentModule = FUSE","category":"page"},{"location":"act.html","page":"act parameters","title":"act parameters","text":"import FUSE # hide\nact = FUSE.ParametersActors()","category":"page"},{"location":"inits.html#Initialization","page":"Init routines","title":"Initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"CurrentModule = IMAS","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Recall that FUSE actors operate exclusively on IMAS.dd data. As such, to run any actor, one has to first initialize IMAS.dd with some data. This can be done in a number of ways:","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Manually/Interactivelly (eg. in the REPL or a Jupyter sesion)\nStarting from 0D ini and act parameters (same spirit of OMFIT's PRO_create module)\nBy reading in an existing OMAS JSON data structure with json2imas\nStarting from GA Systems Code output, then to ini, and finally to dd","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"The following init...() routines initialize dd from 0D parameters (method #2)","category":"page"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"CurrentModule = FUSE","category":"page"},{"location":"inits.html#High-level-Initialization","page":"Init routines","title":"High-level Initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init","text":"init(\n dd::IMAS.dd,\n ini::ParametersAllInits,\n act::ParametersAllActors;\n do_plot::Bool=false,\n initialize_hardware::Bool=true,\n initialize_pulse_schedule::Bool=true,\n restore_expressions::Bool=true,\n verbose::Bool=false)\n\nInitialize dd starting from ini and act parameters\n\nFUSE provides this high-level init function to populate dd starting from the ini parameters.\n\nThis function essentially calls all other FUSE.init... functions in FUSE.\n\nFor most studies, calling this high level function is sufficient.\n\n\n\n\n\n","category":"method"},{"location":"inits.html#Use-cases-initialization","page":"Init routines","title":"Use-cases initialization","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init(case::Symbol; do_plot:Bool=false, kw...)","category":"page"},{"location":"inits.html#FUSE.init-Tuple{Symbol}","page":"Init routines","title":"FUSE.init","text":"init(case::Symbol; do_plot::Bool=false, kw...)\n\nInitialize dd, ini, act based on a given use-case.\n\nReturns a tuple with dd, ini, act.\n\n\n\n\n\n","category":"method"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"","category":"page"},{"location":"inits.html#Low-level-initialization-routines","page":"Init routines","title":"Low-level initialization routines","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"Below are the initialization functions specific to IDSs in the dd data structure. These can be called for a fine control on what IDSs are initialized and how.","category":"page"},{"location":"inits.html#balance-of-plant!","page":"Init routines","title":"balance of plant!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_balance_of_plant!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_balance_of_plant!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_balance_of_plant!","text":"init_balance_of_plant!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.balance_of_plant starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#build!","page":"Init routines","title":"build!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_build!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_build!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_build!","text":"init_build!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.build starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#core-profiles!","page":"Init routines","title":"core profiles!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_core_profiles!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_core_profiles!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_core_profiles!","text":"init_core_profiles!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.core_profiles starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#core-sources!","page":"Init routines","title":"core sources!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_core_sources!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_core_sources!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_core_sources!","text":"init_core_sources!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.nbi, dd.ec_launchers, dd.ic_antennas, dd.lh_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#currents!","page":"Init routines","title":"currents!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_currents!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_currents!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_currents!","text":"init_currents!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.core_profiles and dd.core_sources ohmic and bootstrap currents and sources starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#ec","page":"Init routines","title":"ec","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_ec(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_ec-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_ec","text":"init_ec(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.ec_launchers starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#equilibrium!","page":"Init routines","title":"equilibrium!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_equilibrium!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_equilibrium!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_equilibrium!","text":"init_equilibrium!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.equilibrium starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#expressions","page":"Init routines","title":"expressions","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_expressions(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#ic","page":"Init routines","title":"ic","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_ic(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_ic-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_ic","text":"init_ic(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.ic_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#lh","page":"Init routines","title":"lh","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_lh(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_lh-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_lh","text":"init_lh(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.lh_antennas starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#missing-from-ods!","page":"Init routines","title":"missing from ods!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_missing_from_ods!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_missing_from_ods!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_missing_from_ods!","text":"init_missing_from_ods!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize missing IDSs from ODS, only if ini.general.init_from == :ods.\n\n\n\n\n\n","category":"method"},{"location":"inits.html#nb","page":"Init routines","title":"nb","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_nb(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_nb-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_nb","text":"init_nb(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.nbi starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pf-active!","page":"Init routines","title":"pf active!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pf_active!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pf_active!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pf_active!","text":"init_pf_active!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.pf_active starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pl","page":"Init routines","title":"pl","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pl(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pl-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pl","text":"init_pl(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.pellet_launcher starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pulse-schedule!","page":"Init routines","title":"pulse schedule!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pulse_schedule!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_pulse_schedule!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_pulse_schedule!","text":"init_pulse_schedule!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd(); simplify_time_traces::Float64=0.1)\n\nInitialize dd.pulse_schedule starting from ini and act parameters\n\n\n\n\n\n","category":"method"},{"location":"inits.html#pulse-schedule-postion-control","page":"Init routines","title":"pulse schedule postion control","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_pulse_schedule_postion_control(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#requirements!","page":"Init routines","title":"requirements!","text":"","category":"section"},{"location":"inits.html","page":"Init routines","title":"Init routines","text":"FUSE.init_requirements!(::IMAS.dd, ::FUSE.ParametersAllInits, ::FUSE.ParametersAllActors)","category":"page"},{"location":"inits.html#FUSE.init_requirements!-Tuple{IMASdd.dd, FUSE.ParametersAllInits, FUSE.ParametersAllActors}","page":"Init routines","title":"FUSE.init_requirements!","text":"init_requirements!(dd::IMAS.dd, ini::ParametersAllInits, act::ParametersAllActors, dd1::IMAS.dd=IMAS.dd())\n\nInitialize dd.requirements ini.requirements\n\n\n\n\n\n","category":"method"},{"location":"imas.html#Inner-workings-of-IMASdd.jl-and-IMAS.jl","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Inner workings of IMASdd.jl and IMAS.jl","text":"","category":"section"},{"location":"imas.html","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Inner workings of IMASdd.jl and IMAS.jl","text":"These two packages implement the functionalities of the ITER IMAS infrastructure in native Julia.","category":"page"},{"location":"imas.html#Data-types","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Data types","text":"","category":"section"},{"location":"imas.html#Expressions","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Expressions","text":"","category":"section"},{"location":"imas.html#Resizing-arrays-of-structures","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Resizing arrays of structures","text":"","category":"section"},{"location":"imas.html#Handling-of-time","page":"Inner workings of IMASdd.jl and IMAS.jl","title":"Handling of time","text":"","category":"section"},{"location":"ini.html#ini-Parameters","page":"ini parameters","title":"ini Parameters","text":"","category":"section"},{"location":"ini.html","page":"ini parameters","title":"ini parameters","text":"CurrentModule = FUSE","category":"page"},{"location":"ini.html","page":"ini parameters","title":"ini parameters","text":"import FUSE # hide\nini = FUSE.ParametersInits(; n_ic=1, n_nb=1, n_ec=1, n_lh=1, n_pl=1, n_layers=1)","category":"page"},{"location":"notice.html#FUSE.jl-Notice","page":"Notice","title":"FUSE.jl Notice","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"The purpose of this NOTICE file is to provide legal notices and acknowledgments that must be displayed to users in any derivative works or distributions. This file does not alter the terms of the Apache 2.0 license that governs the use and distribution of the FUSE.jl package.","category":"page"},{"location":"notice.html#Development-Attribution","page":"Notice","title":"Development Attribution","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"FUSE.jl was originally developed under the FUSE project by the Magnetic Fusion Energy group at General Atomics.","category":"page"},{"location":"notice.html#Citation","page":"Notice","title":"Citation","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"If this software contributes to an academic publication, please cite it as follows:","category":"page"},{"location":"notice.html","page":"Notice","title":"Notice","text":"@article{meneghini2024fuse,\nauthor = {Meneghini, O. and Slendebroek, T. and Lyons, B.C. and McLaughlin, K. and McClenaghan, J. and Stagner, L. and Harvey, J. and Neiser, T.F. and Ghiozzi, A. and Dose, G. and Guterl, J. and Zalzali, A. and Cote, T. and Shi, N. and Weisberg, D. and Smith, S.P. and Grierson, B.A. and Candy, J.},\ndoi = {10.48550/arXiv.2409.05894},\njournal = {arXiv},\ntitle = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}},\nyear = {2024}\n}","category":"page"},{"location":"notice.html#Trademark-Notice","page":"Notice","title":"Trademark Notice","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"The names \"General Atomics\", and any associated logos or images, are trademarks of General Atomics. Use of these trademarks without prior written consent from General Atomics is strictly prohibited. Users cannot imply endorsement by General Atomics or contributors to the project simply because the project is part of their work.","category":"page"},{"location":"notice.html#Copyright","page":"Notice","title":"Copyright","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"Copyright (c) 2024 General Atomics","category":"page"},{"location":"notice.html#Version","page":"Notice","title":"Version","text":"","category":"section"},{"location":"notice.html","page":"Notice","title":"Notice","text":"Version: v2.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBalanceOfPlant.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.minimum_first_wall_thickness\nMinimum first wall thicknessType: Entry{Float64}\nUnits: m\nDefault: 0.02","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.blanket_multiplier\nNeutron thermal power multiplier in blanketType: Entry{Float64}\nUnits: -\nDefault: 1.2","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.thermal_power_extraction_efficiency\nFraction of thermal power that is carried out by the coolant at the blanket interface, rather than being lost in the surrounding strutures.Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorBlanket.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.free_boundary\nConvert fixed boundary equilibrium to free boundary oneType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.clear_workdir\nClean the temporary workdir for CHEASEType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCHEASE.rescale_eq_to_ip\nScale equilibrium to match IpType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCHEASE.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.rebuild_wall\nRebuild wall based on equilibriumType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.n_points\nNumber of points used for cross-sectional outlinesType: Entry{Int64}\nUnits: -\nDefault: 101","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.divertor_size\nDivertor size as fraction of plasma minor radiusType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCXbuild.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.N\nNumber of launched photonsType: Entry{Int64}\nUnits: -\nDefault: 100000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.r\nVector of r at outermidplaneType: Entry{Vector{Float64}}\nUnits: m\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.q\nVector of parallel power density at outer midplaneType: Entry{Vector{Float64}}\nUnits: W m^-2\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.levels\nIf Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOLType: Entry{Union{Int64, Vector}}\nUnits: -\nDefault: 20","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.merge_wall\nMerge dd.wall in mesh for the heat flux Type: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.step\nStep for discretization of the default wall mesh (dd.wall)Type: Entry{Float64}\nUnits: m\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreRadHeatFlux.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreTransport.model\nTransport actor to runType: Switch{Symbol}\nUnits: -\nOptions: FluxMatcher, EPEDProfiles, none\nDefault: FluxMatcher","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCoreTransport.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.model\nCosting modelType: Switch{Symbol}\nUnits: -\nOptions: ARIES, Sheffield\nDefault: ARIES","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.construction_start_year\nYear that plant construction beginsType: Entry{Int64}\nUnits: year\nDefault: 2024","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.future_inflation_rate\nPredicted average rate of future inflationType: Entry{Float64}\nUnits: -\nDefault: 0.025","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.plant_lifetime\nLifetime of the plantType: Entry{Int64}\nUnits: year\nDefault: 40","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.availability\nAvailability fraction of the plantType: Entry{Float64}\nUnits: -\nDefault: 0.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.production_increase\nFactor by which production of ReBCO multipliesType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCosting.learning_rate\nLearning rate for ReBCO technology productionType: Entry{Float64}\nUnits: -\nDefault: 0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.land_space\nPlant site space requiredType: Entry{Float64}\nUnits: acres\nDefault: 1000.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.building_volume\nVolume of the tokmak buildingType: Entry{Float64}\nUnits: m^3\nDefault: 140000.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.interest_rate\nAnnual interest rate fraction of direct capital costType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.indirect_cost_rate\nIndirect cost associated with construction, equipment, services, engineering construction management and owners costType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.escalation_fraction\nYearly escalation fraction based on risk assessmentType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingARIES.blanket_lifetime\nLifetime of the blanketType: Entry{Float64}\nUnits: year\nDefault: 6.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.construction_lead_time\nDuration of constructionType: Entry{Float64}\nUnits: year\nDefault: 8.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.fixed_charge_rate\nConstant dollar fixed charge rateType: Entry{Float64}\nUnits: -\nDefault: 0.078","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.capitalize_blanket\nIf true, include cost of 1st blanket in direct captial costType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.capitalize_divertor\nIf true, include cost of 1st divertor in direct captial costType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.divertor_fluence_lifetime\nDivertor fluence over its lifetimeType: Entry{Float64}\nUnits: MW*yr/m²\nDefault: 10.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCostingSheffield.blanket_fluence_lifetime\nBlanket fluence over its lifetimeType: Entry{Float64}\nUnits: MW*yr/m²\nDefault: 15.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCurrent.model\nCurrent actor to runType: Switch{Symbol}\nUnits: -\nOptions: SteadyStateCurrent, QED, none\nDefault: SteadyStateCurrent","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorCurrent.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCurrent.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorCurrent.vloop_from\nTake vloop from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule, controllers__ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.heat_flux_model\nDivertor heat flux modelType: Switch{Symbol}\nUnits: -\nOptions: lengyel, stangeby\nDefault: lengyel","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.impurities\nVector of impurity speciesType: Entry{Vector{Symbol}}\nUnits: -\nDefault: Symbol[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.impurities_fraction\nVector of impurity fractionsType: Entry{Vector{Float64}}\nUnits: -\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.heat_spread_factor\nHeat flux expansion factor in the private flux region (eg. due to transport) should be >= 1.0Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.thermal_power_extraction_efficiency\nFraction of thermal power that is carried out by the coolant at the divertor interface, rather than being lost in the surrounding strutures.Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDivertors.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorDynamicPlasma.Δt\nEvolve for ΔtType: Entry{Float64}\nUnits: s","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorDynamicPlasma.Nt\nNumber of time steps during evolutionType: Entry{Int64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_transport\nEvolve the transportType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_pedestal\nEvolve the pedestalType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_hcd\nEvolve the heating and current driveType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_current\nEvolve the plasma currentType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_equilibrium\nEvolve the equilibriumType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.evolve_pf_active\nEvolve the PF currentsType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.ip_controller\nUse controller to change v_loop to match desired IpType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.time_derivatives_sources\nInclude time-derivative sourcesType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorDynamicPlasma.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.rho_nml\nDefines rho at which the no man's land region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.rho_ped\nDefines rho at which the pedestal region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.T_ratio_pedestal\nRatio of ion to electron temperatures (or rho at which to sample for that ratio, if negative; or rhonml-(rhoped-rho_nml) if 0.0)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.ped_factor\nPedestal height multiplier (width scaled by sqrt of this factor)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.only_powerlaw\nEPED-NN uses power-law pedestal fit (without NN correction)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.βn_from\nTake βn from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.ne_ped_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEPED.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPED.warn_nn_train_bounds\nEPED-NN raises warnings if querying cases that are certainly outside of the training rangeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_shaping\nShaping coefficient for the temperature profileType: Entry{Float64}\nUnits: -\nDefault: 1.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.ne_shaping\nShaping coefficient for the density profileType: Entry{Float64}\nUnits: -\nDefault: 1.8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_ratio_pedestal\nIon to electron temperature ratio in the pedestalType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEPEDprofiles.T_ratio_core\nIon to electron temperature ratio in the coreType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.model\nEquilibrium actor to runType: Switch{Symbol}\nUnits: -\nOptions: Solovev, CHEASE, TEQUILA\nDefault: TEQUILA","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.symmetrize\nForce equilibrium up-down symmetry with respect to magnetic axisType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.j_p_from\nTake j_tor and pressure profiles from this IDSType: Switch{Symbol}\nUnits: -\nOptions: equilibrium, core_profiles\nDefault: core_profiles","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorEquilibrium.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.vacuum_r0_b0_from\nTake vacuumr0b0 from this IDSType: Switch{Symbol}\nUnits: -\nOptions: equilibrium, pulse_schedule\nDefault: pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorEquilibrium.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.rho_transport\nrho core transport gridType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.turbulence_model\nTurbulence model to useType: Switch{Symbol}\nUnits: -\nOptions: TGLF, QLGYRO, none\nDefault: TGLF","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxCalculator.neoclassical_model\nNeocalssical model to useType: Switch{Symbol}\nUnits: -\nOptions: neoclassical, none\nDefault: neoclassical","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.rho_transport\nρ transport gridType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_Ti\nIon temperature :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_Te\nElectron temperature :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_densities\nDensities :fixed, or electron flux-match and rest match ne scale :flux_match, or Dict to specify which species are :flux_match, kept :fixed, used to enforce :quasi_neutrality, or scaled to :match_ne_scaleType: Entry{Union{Symbol, AbstractDict}}\nUnits: -\nDefault: flux_match","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_rotation\nRotation :flux_match or keep :fixedType: Switch{Symbol}\nUnits: -\nOptions: flux_match, fixed\nDefault: fixed","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.evolve_pedestal\nEvolve the pedestal within the transport solverType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.find_widths\nRuns turbulent transport actor TJLF finding widths after first iterationType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.max_iterations\nMaximum optimizer iterationsType: Entry{Int64}\nUnits: -\nDefault: 500","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.optimizer_algorithm\nOptimizing algorithm used for the flux matchingType: Switch{Symbol}\nUnits: -\nOptions: anderson, newton, trust_region, simple, none\nDefault: anderson","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.step_size\nStep size for each algorithm iteration (note this has a different meaning for each algorithm)Type: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.Δt\nEvolve for Δt (Inf for steady state)Type: Entry{Float64}\nUnits: s\nDefault: Inf","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.save_input_tglf_folder\nSave the intput.tglf files in designated folder at the last iterationType: Entry{String}\nUnits: -\nDefault: ``","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.relax\nRelaxation on the final solutionType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorFluxMatcher.norms\nRelative normalization of different channelsType: Entry{Vector{Float64}}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxMatcher.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorFluxSwing.operate_oh_at_j_crit\nIf true it makes the OH operate at its current limit (within specified dd.requirements.coiljmargin`).","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"The flattop duration and maximum toroidal magnetic field follow from that. Otherwise we evaluate what is the current needed for dd.requirements.flattopduration, which may or may not exceed the OH critical current limit. If dd.requirements.flattopduration is not set, then operateohatjcrit is assumed. * Type: Entry{Bool} * Units: - * Default: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.ec_model\nEC source actor to runType: Switch{Symbol}\nUnits: -\nOptions: ECsimple, none\nDefault: ECsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.ic_model\nIC source actor to runType: Switch{Symbol}\nUnits: -\nOptions: ICsimple, none\nDefault: ICsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.lh_model\nLH source actor to runType: Switch{Symbol}\nUnits: -\nOptions: LHsimple, none\nDefault: LHsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.nb_model\nNB source actor to runType: Switch{Symbol}\nUnits: -\nOptions: NBsimple, RABBIT, none\nDefault: NBsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHCD.pellet_model\nPellet source actor to runType: Switch{Symbol}\nUnits: -\nOptions: Pelletsimple, none\nDefault: Pelletsimple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.error_on_technology\nError if build stresses and current limits are not metType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.error_on_performance\nError if requested Bt and flattop duration are not metType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorHFSsizing.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.maintenance\nScheme for installation/removal of in-vessel componentsType: Switch{Symbol}\nUnits: -\nOptions: vertical, horizontal, none\nDefault: none","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.tor_modularity\nNumber of toroidal modules of blanket normalized to number of TF coilsType: Entry{Int64}\nUnits: -\nDefault: 2","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.pol_modularity\nNumber of poloidal modules of each toroidal blanket sectorType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorLFSsizing.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNBI.model\nNBI modelType: Switch{Symbol}\nUnits: -\nOptions: simple, RABBIT\nDefault: simple","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeoclassical.model\nNeoclassical model to runType: Switch{Symbol}\nUnits: -\nOptions: changhinton, neo, hirshmansigmar\nDefault: hirshmansigmar","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeoclassical.rho_transport\nrhotornorm values to compute neoclassical fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeutronics.N\nNumber of particlesType: Entry{Int64}\nUnits: -\nDefault: 100000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorNeutronics.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.green_model\nModel used for the coils Green function calculationsType: Switch{Symbol}\nUnits: -\nOptions: point, quad\nDefault: quad","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.update_equilibrium\nOverwrite target equilibrium with the one that the coils can actually makeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFactive.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.symmetric\nForce PF coils location to be up-down symmetricType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.update_equilibrium\nOverwrite target equilibrium with the one that the coils can actually makeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.model\nCoil placement strategyType: Switch{Symbol}\nUnits: -\nOptions: none, uniform, optimal\nDefault: optimal","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPFdesign.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.r\nVector of r at outermidplaneType: Entry{Vector{Float64}}\nUnits: m\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.q\nVector of parallel power density at outer midplaneType: Entry{Vector{Float64}}\nUnits: W m^-2\nDefault: Float64[]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.levels\nIf Int it defines number of levels in SOL, if vector it corresponds to the psi levels to build SOLType: Entry{Union{Int64, Vector{Float64}}}\nUnits: -\nDefault: 20","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.merge_wall\nMerge dd.wall in mesh for the heat flux Type: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.step\nStep for discretization of the default wall mesh (dd.wall)Type: Entry{Float64}\nUnits: m\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorParticleHeatFlux.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.wall_precision\nPrecision for making wall quadralateralsType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.min_n_segments\nMinimum number of quadralateralsType: Entry{Int64}\nUnits: -\nDefault: 15","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPassiveStructures.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.rho_nml\nDefines rho at which the no man's land region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.rho_ped\nDefines rho at which the pedestal region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.density_match\nMatching density based on ne_ped or line averaged densityType: Switch{Symbol}\nUnits: -\nOptions: ne_line, ne_ped\nDefault: ne_ped","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.model\nPedestal model to useType: Switch{Symbol}\nUnits: -\nOptions: EPED, WPED, auto, none\nDefault: EPED","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.βn_from\nTake βn from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.ne_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPedestal.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPedestal.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPowerNeeds.model\nPower plant electrical needs modelType: Switch{Symbol}\nUnits: -\nOptions: thermal_power_fraction, EU_DEMO, FUSE\nDefault: FUSE","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorPowerNeeds.thermal_power_fraction\nFraction of the gross electrical power generated by the thermal cycle (if model==:thermal_power_fraction)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorPowerNeeds.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.Δt\nEvolve for Δt (Inf for steady state)Type: Entry{Float64}\nUnits: s\nDefault: Inf","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.Nt\nNumber of time steps during evolutionType: Entry{Int64}\nUnits: -\nDefault: 100","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQED.solve_for\nSolve for specified Ip or VloopType: Switch{Symbol}\nUnits: -\nOptions: ip, vloop\nDefault: ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorQED.vloop_from\nTake vloop from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule, controllers__ip","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.model\nImplementation of QLGYROType: Switch{Symbol}\nUnits: -\nOptions: QLGYRO\nDefault: QLGYRO","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.ky\nMax kyType: Entry{Float64}\nUnits: -\nDefault: 1.6","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.nky\nNumber of ky modesType: Entry{Int64}\nUnits: -\nDefault: 16","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.cpu_per_ky\nNumber of cpus per kyType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.kygrid_model\nTGLF ky grid modelType: Entry{Int64}\nUnits: -\nDefault: 0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.sat_rule\nSaturation ruleType: Switch{Symbol}\nUnits: -\nOptions: sat1, sat2, sat3\nDefault: sat1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.n_field\n1:phi, 2:phi+apar, 3:phi+apar+bparType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.delta_t\nCGYRO step size Type: Entry{Float64}\nUnits: -\nDefault: 0.005","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.max_time\nMax simulation time (a/cs)Type: Entry{Float64}\nUnits: -\nDefault: 100.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.rho_transport\nrhotornorm values to compute QLGYRO fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorQLGYRO.lump_ions\nLumps the fuel species (D,T) as well as the impurities togetherType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleEC.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleIC.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleLH.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSimpleNB.ηcd_scale\nScaling factor for nominal current drive efficiencyType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.ngrid\nGrid size (for R, Z follows proportionally to plasma elongation)Type: Entry{Int64}\nUnits: -\nDefault: 129","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.qstar\nInitial guess of kink safety factorType: Entry{Float64}\nUnits: -\nDefault: 1.5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.alpha\nInitial guess of constant relating to pressureType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSolovev.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorSolovev.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStabilityLimits.models\nModels used for checking plasma stability limits: [:densitylimits, :betalimits, :currentlimits, :defaultlimits, :unknown, :κcontrollability, :betamodel105, :q95gt2, :betabernard1983, :gwdensity, :betatuda1985, :betatroyon1985, :q08gt2, :betatroyon1984]Type: Entry{Vector{Symbol}}\nUnits: -\nDefault: [:default_limits]","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStabilityLimits.raise_on_breach\nRaise an error when one or more stability limits are breachedType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.max_iter\nmax number of transport-equilibrium iterationsType: Entry{Int64}\nUnits: -\nDefault: 5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.convergence_error\nConvergence error threshold (relative change in current and pressure profiles)Type: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStationaryPlasma.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSteadyStateCurrent.allow_floating_plasma_current\nZero loop voltage if non-inductive fraction exceeds 100% of the target IpType: Entry{Bool}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorSteadyStateCurrent.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStresses.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorStresses.n_points\nNumber of grid pointsType: Entry{Int64}\nUnits: -\nDefault: 5","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.free_boundary\nConvert fixed boundary equilibrium to free boundary oneType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_radial_grid_points\nNumber of TEQUILA radial grid pointsType: Entry{Int64}\nUnits: -\nDefault: 31","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_fourier_modes\nNumber of modes for Fourier decompositionType: Entry{Int64}\nUnits: -\nDefault: 8","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_MXH_harmonics\nNumber of Fourier harmonics in MXH representation of flux surfacesType: Entry{Int64}\nUnits: -\nDefault: 4","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.number_of_iterations\nNumber of TEQUILA iterationsType: Entry{Int64}\nUnits: -\nDefault: 1000","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.relax\nRelaxation on the Picard iterationsType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.tolerance\nTolerance for terminating iterationsType: Entry{Float64}\nUnits: -\nDefault: 0.0001","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.ip_from\nTake ip from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, equilibrium, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.fixed_grid\nFix P and Jt on this rho gridType: Switch{Symbol}\nUnits: -\nOptions: poloidal, toroidal\nDefault: toroidal","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTEQUILA.debug\nPrint debug information withing TEQUILA solveType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.R\nPsi R axisType: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTEQUILA.Z\nPsi Z axisType: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.model\nImplementation of TGLFType: Switch{Symbol}\nUnits: -\nOptions: TGLF, TGLFNN, TJLF\nDefault: TGLFNN","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.sat_rule\nSaturation ruleType: Switch{Symbol}\nUnits: -\nOptions: sat0, sat0quench, sat1, sat1geo, sat2, sat3\nDefault: sat1","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.electromagnetic\nElectromagnetic or electrostaticType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.user_specified_model\nUse a user specified TGLF-NN model stored in TGLFNN/modelsType: Entry{String}\nUnits: -\nDefault: ``","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.rho_transport\nrhotornorm values to compute tglf fluxes onType: Entry{AbstractVector{Float64}}\nUnits: -\nDefault: 0.25:0.1:0.85","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.warn_nn_train_bounds\nRaise warnings if querying cases that are certainly outside of the training rangeType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorTGLF.custom_input_files\nSets up the input file that will be run with the custom input file as a maskType: Entry{Union{Vector{<:TGLFNN.InputTGLF}, Vector{<:TJLF.InputTJLF}}}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorTGLF.lump_ions\nLumps the fuel species (D,T) as well as the impurities togetherType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.model\nPower plant heat cycle efficiencyType: Switch{Symbol}\nUnits: -\nOptions: fixed_plant_efficiency, network, surogate\nDefault: surogate","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.fixed_plant_efficiency\nOverall thermal cycle efficiency (if model=:fixed_plant_efficiency)Type: Entry{Float64}\nUnits: -\nDefault: 0.35","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorThermalPlant.verbose\nVerboseType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorVerticalStability.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.ped_to_core_fraction\nRatio of edge (@rho=0.9) to core stored energy [0.05 for L-mode, 0.3 for neg-T plasmas]Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.rho_ped\nDefines rho at which the edge region startsType: Entry{Float64}\nUnits: -","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.ne_ped_from\nTake ne_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"note: act.ActorWPED.zeff_ped_from\nTake zeff_ped from this IDSType: Switch{Symbol}\nUnits: -\nOptions: core_profiles, summary, pulse_schedule","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWPED.do_plot\nStore the output dds of the workflow runType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWholeFacility.update_plasma\nRun plasma related actorsType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"act_details.html","page":"-","title":"-","text":"tip: act.ActorWholeFacility.update_build\nOptimize tokamak buildType: Entry{Bool}\nUnits: -\nDefault: true","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"amns_data.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].extrapolation_type\nExtrapolation strategy when leaving the domain. The first value of the vector describes the behaviour at lower bound, the second describes the at upper bound. Possible values: 0=none, report error; 1=boundary value; 2=linear extrapolationData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].interpolation_type\nInterpolation strategy in this coordinate direction. Integer flag: 0=discrete (no interpolation); 1=linear; ...Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].label\nDescription of coordinate (e.g. \"Electron temperature\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].spacing\nFlag for specific coordinate spacing (for optimization purposes). Integer flag: 0=undefined; 1=uniform; ...Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].transformation\nCoordinate transformation applied to coordinate values stored in coord. Integer flag: 0=none; 1=log10; 2=lnData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].units\nUnits of coordinate (e.g. eV)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].value_labels\nString description of discrete coordinate values (if interpolation_type=0). E.g., for spectroscopic lines, the spectroscopic description of the transition.Data Type: STR_1D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.coordinate_system[:].coordinate[:].values\nCoordinate valuesUnits: units given by coordinate_system(:)/coordinate(:)/units\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_0d\n0D table describing the process dataUnits: units given by process(:)/results_units\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_1d\n1D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_1D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_2d\n2D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_2D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_3d\n3D table describing the process dataUnits: units given by process(:)/results_units\nData Type: FLT_3D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_4d\n4D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_4D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_5d\n5D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_5D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].table_6d\n6D table describing the process dataUnits: units given by process(i1)/results_units\nData Type: FLT_6D\nCoordinates: [\"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\", \"amns_data.coordinate_system[:].coordinate[:].values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].charge_state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].citation\nReference to publication(s)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].coordinate_index\nIndex in tables_coord, specifying what coordinate systems to use for this process (valid for all tables)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].label\nString identifying the process (e.g. EI, RC, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].charge\nCharge number of the participantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].label\nString identifying reaction participant (e.g. \"D\", \"e\", \"W\", \"CD4\", \"photon\", \"n\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].mass\nMass of the participantUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].metastable\nAn array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].metastable_label\nLabel identifying in text form the metastableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].multiplicity\nMultiplicity in the reactionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].relative_charge\nThis is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundleData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].products[:].role.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].charge\nCharge number of the participantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].label\nString identifying reaction participant (e.g. \"D\", \"e\", \"W\", \"CD4\", \"photon\", \"n\")Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].mass\nMass of the participantUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].metastable\nAn array identifying the metastable; if zero-length, then not a metastable; if of length 1, then the value indicates the electronic level for the metastable (mostly used for atoms/ions); if of length 2, then the 1st would indicate the electronic level and the second the vibrational level for the metastable (mostly used for molecules and molecular ions); if of length 3, then the 1st would indicate the electronic level, the second the vibrational level and the third the rotational level for the metastable (mostly used for molecules and molecular ions)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].metastable_label\nLabel identifying in text form the metastableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].multiplicity\nMultiplicity in the reactionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].relative_charge\nThis is a flag indicating that charges are absolute (if set to 0), relative (if 1) or irrelevant (-1); relative would be used to categorize the ionization reactions from i to i+1 for all charge states; in the case of bundles, the +1 relative indicates the next bundleData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].reactants[:].role.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_label\nDescription of the process result (rate, cross section, sputtering yield, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_transformation\nTransformation of the process result. Integer flag: 0=no transformation; 1=10^; 2=exp()Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].result_units\nUnits of the process resultData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].source\nFilename or subroutine name used to provide this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.process[:].table_dimension\nTable dimensionality of the process (1 to 6), valid for all charge states. Indicates which of the tables is filled (below the charge_state node)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].description\nDescription of this data entryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].run\nWhich run number is the active run number for this versionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].data_entry[:].shot\nShot number = Mass*1000+Nuclear_chargeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].date\nDate of this releaseData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.release[:].description\nDescription of this releaseData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: amns_data.z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"b_field_non_axisymmetric.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.configuration\nIn case of a constant (single time slice) b_field description, name of the corresponding scenario/configurationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.control_surface_names\nList of control surface names, refers to the ../timeslice/controlsurface indexData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal\nNormal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_normal_fourier\nFourier coefficients of the normal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: CPX_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_r\nR component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_tor\nToroidal component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].b_field_z\nZ component of the vacuum error magnetic field on the various surface pointsUnits: T\nData Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\", \"b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].n_tor\nToroidal mode numberData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].normal_vector.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].control_surface[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].control_surface[:].phi\nToroidal angle array, on which the Fourier decomposition is carried outUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_r\nR component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_tor\nToroidal component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.b_field_z\nZ component of the vacuum error magnetic fieldUnits: T\nData Type: FLT_3D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].field_map.ripple_amplitude\nValue of (bfieldmax-bfieldmin)/(bfieldmax+bfieldmin), where bfieldmax resp. bfieldmin) is the maximum (resp. minimum) of the magnetic field amplitude over a 2pi rotation in toroidal angle phi at a given R, Z position. Data Type: FLT_2D\nCoordinates: [\"b_field_non_axisymmetric.time_slice[:].field_map.grid.r\", \"b_field_non_axisymmetric.time_slice[:].field_map.grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: b_field_non_axisymmetric.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.Q_plant\nElectricity gain of the plant (ratio of net electric / plant electricity during operation)Data Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_net\nNet electric powerUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].power\nElectrical power used to operate the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.system[:].subsystem[:].power\nElectrical power used to operate the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_electric_plant_operation.total_power\nTotal Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.generator_conversion_efficiency\nConversion efficiency of thermal to electric power of the steam cycleData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.breeder\nThe heat flow towards the breeder.Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.divertor\nThe heat flow towards the divertorUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.heat_load.wall\nThe heat flow towards the wall.Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.power_cycle_type\nType of primary power cycle, :brayton = gas, :rankine = steamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.power_electric_generated\nThe net electric power produced by the thermal plant, equal tot the power produced by turbines LESS the power consumed by pumps and compressorsUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].name\nName of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].massflow\nMass Flow Rate of the fluidUnits: kg/s\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].mechanicalPower\nShaft power associated with the component, (+) = into the system, (-) = out of the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].name\nName of the portData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].pressure\nFluid pressureUnits: Bar\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].temperature\nFluid TemperatureUnits: C\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].component[:].port[:].thermalPower\nHeattransfer rate of the component, (+) = into the system, (-) = out of the systemUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].index\nIndex of the system, used to generate functionsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.total_heat_rejected\nThe total heat flow being rejected from the thermal plantUnits: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.power_plant.total_heat_supplied\nThe total heat flow being supplied to the thermal Plant (Fusion thermal power).Units: W\nData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.thermal_efficiency_cycle\nThe fractional thermal effiency of the power cycle. Calculated as 1-Qout/QinData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.thermal_efficiency_plant\nThe fractional thermal effiency of the entire BOP thermal plant, inlcudes all of the individual cycles. Calculated as 1-Qout/QinData Type: FLT_1D\nCoordinates: [\"balance_of_plant.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: balance_of_plant.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"barometry.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].calibration_coefficient\nCoefficient used for converting raw signal into absolute pressureUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].name\nName of the gaugeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].pressure.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"barometry.gauge[:].pressure.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].pressure.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.gauge[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: barometry.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].material\nMaterial of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].midplane_thickness\nThickness of layer evaluated at the midplaneUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].layer[:].name\nName of the blanket layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].name\nName of the blanket moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].peak_escape_flux\nMaximum neutron flux escaping from the back of the blanket moduleUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].peak_wall_flux\nMaximum neutron flux at the first wallUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_incident_neutrons\nTotal incident neutron power on the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_incident_radiated\nTotal incident radiative power on the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_extracted\nTotal thermal power that is extracted from the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_neutrons\nTotal neutron power (deposited + generated) in the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].power_thermal_radiated\nTotal radiated power (incident - reflected) in the blanket moduleUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.module[:].time_slice[:].tritium_breeding_ratio\nNumber of tritium atoms for each incident neutron (TBR)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: blanket.tritium_breeding_ratio\nNumber of tritium atoms created for each fusion neutron (TBR)Data Type: FLT_1D\nCoordinates: [\"blanket.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].power.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.channel[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].power.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity\nIndicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity_timed.data\nDataData Type: INT_1D\nCoordinates: [\"bolometer.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid.volume_element\nVolume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"bolometer.grid.dim1\", \"bolometer.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_density.data\nDataUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"bolometer.grid.dim1\", \"bolometer.grid.dim2\", \"bolometer.power_density.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_density.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_inside_lcfs\nRadiated power from the plasma inside the Last Closed Flux Surface, reconstructed from bolometry dataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_total\nTotal radiated power reconstructed from bolometry dataUnits: W\nData Type: FLT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.power_radiated_validity\nValidity flag related to the radiated power reconstructionsData Type: INT_1D\nCoordinates: [\"bolometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bolometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].filter.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].filter.wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].intensity.data\nDataUnits: (counts) s^-1\nData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.data\nDataData Type: FLT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.channel[:].zeff_line_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"bremsstrahlung_visible.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"bremsstrahlung_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: bremsstrahlung_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.divertors.lower.installed\n1 if a lower divertor is installedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.divertors.upper.installed\n1 if a upper divertor is installedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.flattop\nTotal flux required for the plasma flattopUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.pf\nContribution of vertical field from PF coils to flux swingUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.flux_swing.rampup\nTotal flux required for the plasma rampupUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].area\nCross sectional area of the layerUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].end_radius\nEnd radius of the layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].identifier\nInteger to identify the same layer on the high-field-side and low-field-sideData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].material\nMaterial of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].name\nName of the layerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.layer[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].shape\nInteger to identify the physical shape of the layerData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].shape_parameters\nList of the shape specific parameters for given shape typeData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].side\nInteger set to -1 if layer is on the low-field-side and 1 if layer is on the high-field-side. 0 for plasma. 2 for inner (eg. OH) and 3 for outer (eg. cryostat)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].start_radius\nStart radius of the layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].thickness\nRadial thickness of layerUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].type\nLayer type code","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"vacuum (use this to set mimimum radius for OH)\nOH\nTF\nBL\nShielding\nWall","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"-1) Vacuum vessel * Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].volume\nVolume of the layerUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.layer[:].volume_no_structures\nVolume of the layer without structuresUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.critical_b_field\nCritical magnetic field density to quench superconducting OHUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.critical_j\nCritical current density to quench superconducting OHUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.flattop_duration\nEstimated duration of the flattopUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.max_b_field\nMaximum magnetic field in the OH solenoid, as required to satisfy rampup and flattop flux consumptionUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.max_j\nMaximum current density in the OH solenoid, as required to satisfy rampup and flattop flux consumptionUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.fraction_steel\nFraction of stainless steel in the OH coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.fraction_void\nFraction of void in the OH coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.material\nMaterial of the OH coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.temperature\nOH coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.oh.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the OH coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].coils_cleareance\nClereance that coils have from other structuresUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].coils_number\nNumber of coils on the railData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].name\nName of the coil railData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.distance\nDistance along the rail skipping gapsUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.pf_active.rail[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.rail[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.pf_active.rail[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.fraction_steel\nFraction of stainless steel in the PF coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.fraction_void\nFraction of void in the PF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.material\nMaterial of the PF coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.temperature\nPF coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.pf_active.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the PF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].area\nCross sectional area of the structureUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].identifier\nString to identify structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].material\nMaterial of the structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].name\nName of the structureData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"build.structure[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].toroidal_angles\nToroidal position(s) of the structureUnits: rad\nData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].toroidal_extent\nToroidal extent of the structureUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].type\nStructure type codeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.structure[:].volume\nVolume of the structureUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.coils_n\nNumber of TF coils around the torusData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.critical_b_field\nCritical magnetic field to quench superconducting TFUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.critical_j\nCritical current density to quench superconducting TFUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.max_b_field\nMaximum magnetic field evaluated at the TF high-field sideUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.max_j\nMaximum current density in the TF solenoidUnits: A/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.ripple\nFraction of toroidal field ripple evaluated at the outermost radius of the plasma chamberData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.JxB_strain\nFraction of maximum JxB strain over maximum total strain on the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.fraction_steel\nFraction of stainless steel in the TF coils cross-sectional areasData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.fraction_void\nFraction of void in the TF coils cross-sectional area. Void is everything (like coolant) that is not structural nor conductorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.material\nMaterial of the TF coilsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.ratio_SC_to_copper\nFraction of superconductor to copper cross-sectional areas in the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.temperature\nTF coils temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.technology.thermal_strain\nFraction of thermal expansion strain over maximum total strain on the TF coilsData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.tf.wedge_thickness\nThickness of the TF coils wedge evaluatedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: build.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"calorimetry.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].identifier\nID of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.data\nDataUnits: kg.s^-1\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].mass_flow.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].name\nName of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_in.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.cooling_loop[:].temperature_out.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.cooling_loop[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.data\nDataUnits: J\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].energy_cumulated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_cumulated.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].energy_cumulated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_total.data\nDataUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].energy_total.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].identifier\nID of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.data\nDataUnits: kg.s^-1\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].mass_flow.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].mass_flow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].name\nName of the componentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].power.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].power.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_in.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_in.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].temperature_out.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].temperature_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"calorimetry.group[:].component[:].transit_time.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].component[:].transit_time.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"calorimetry.group[:].component[:].transit_time.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].identifier\nID of the groupData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.group[:].name\nName of the groupData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: calorimetry.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.luminance_to_temperature\nLuminance to temperature conversion tableData Type: INT_2D\nCoordinates: [\"1...N\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.optical_temperature\nTemperature of the optical components (digital levels)Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_barrel\nTransmission of the optical barrelData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_mirror\nTransmission of the mirrorData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.calibration.transmission_window\nTransmission of the windowData Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_ir.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame[:].surface_temperature\nSurface temperature image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis). The size of this matrix is assumed to be constant over timeUnits: K\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].distance_separatrix_midplane\nDistance between the measurement position and the separatrix, mapped along flux surfaces to the outboard midplane, in the major radius direction. Positive value means the measurement is outside of the separatrix.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].power_flux_parallel\nParallel heat flux received by the element monitored by the camera, along the distanceseparatrixmidplane coordinateUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"camera_ir.frame_analysis[:].distance_separatrix_midplane\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].sol_heat_decay_length\nHeat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.frame_analysis[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_ir.optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_ir.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].columns_n\nNumber of pixel columns in the horizontal directionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].counts_to_radiance\nCounts to radiance factor, for each pixel of the detector. Includes both the transmission losses in the relay optics and the quantum efficiency of the camera itself, integrated over the wavelength rangeUnits: photons.m^-2.s^-1.sr^-1.counts^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].image_raw\nRaw image (unprocessed) (digital levels). First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].radiance\nRadiance image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Units: photons.m^-2.s^-1.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3\nThird dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.data\nInterpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector pixel). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi (third dimension of this array). The first two dimension correspond to the detector pixels : first dimension : line index (horizontal axis); second dimension: column index (vertical axis). Units: m^-2\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.phi\nToroidal angle (oriented counter-clockwise when viewing from above) of interpolation knotsUnits: rad\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\nMajor radius of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.interpolated.z\nHeight of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.voxel_map\nVoxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.Data Type: INT_3D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim1\", \"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim2\", \"camera_visible.channel[:].detector[:].geometry_matrix.emission_grid.dim3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.voxels_n\nNumber of voxels defined in the voxel_map.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.pixel_indices\nList of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.with_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxelindices. The pixel indices corresponding to an element of this array can be found in pixelindicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.pixel_indices\nList of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\", \"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"camera_visible.channel[:].detector[:].geometry_matrix.without_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].lines_n\nNumber of pixel lines in the vertical directionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].noise\nDetector noise (e.g. read-out noise) (rms counts per second exposure time)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].pixel_to_alpha\nAlpha angle of each pixel in the horizontal axisUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].pixel_to_beta\nBeta angle of each pixel in the vertical axisUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].wavelength_lower\nLower bound of the detector wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].detector[:].wavelength_upper\nUpper bound of the detector wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"camera_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].viewing_angle_alpha_bounds\nMinimum and maximum values of alpha angle of the field of view, where alpha is the agle between the axis X3 and projection of the chord of view on the plane X1X3 counted clockwise from the top view of X2 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.channel[:].viewing_angle_beta_bounds\nMinimum and maximum values of beta angle of the field of view, where beta is the angle between the axis X3 and projection of the chord of view on the plane X2X3 counted clockwise from the top view of X1 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.camera_dimensions\nTotal camera dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.identifier\nID of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_dimensions\nPixel dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixel_position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.pixels_n\nNumber of pixels in each direction (x1, x2)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.camera.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"camera_x_rays.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_humidity.data\nDataData Type: FLT_1D\nCoordinates: [\"camera_x_rays.detector_humidity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_humidity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_temperature.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.detector_temperature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.detector_temperature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.energy_configuration_name\nName of the chosen energy configuration (energy detection threshold)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.energy_threshold_lower\nLower energy detection threshold on each pixel of the detector (photons are counted only if their energy is above this value)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"camera_x_rays.filter_window.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"camera_x_rays.filter_window.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.filter_window.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.frame[:].counts_n\nNumber of counts detected on each pixel during one exposure time. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.name\nName of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.photon_energy\nList of values of the photon energy (coordinate for quantum_effiency)Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.pixel_status\nStatus of each pixel : +1 for valid pixels, -1 for inactive pixels, -2 for mis-calibrated pixels. Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.quantum_efficiency\nQuantum efficiency of the detector, i.e. conversion factor multiplying the number of counts to obtain the number of photons impacting the detector, tabulated as a function of the photon energy, for each pixel of the detector. If all pixels have the same quantum efficiency, just set the size of the first and second dimensions to 1Data Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"camera_x_rays.photon_energy\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.readout_time\nTime used to read out each frame on the detectorUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: camera_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.a\nMass of atom of the diagnostic neutral beam particleUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.doppler_shift.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].bes.doppler_shift.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.doppler_shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.label\nString identifying the diagnostic neutral beam particleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.lorentz_shift.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].bes.lorentz_shift.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.lorentz_shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.radiances.data\nDataUnits: (photons) m^-2.s^-1.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].bes.radiances.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.radiances.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.transition_wavelength\nUnshifted wavelength of the BES transitionUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].bes.z_ion\nIon charge of the diagnostic neutral beam particleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].processed_line[:].shift.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].processed_line[:].width.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].spectrum[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_continuum.data\nDataUnits: m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].spectrum[:].radiance_continuum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_continuum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_spectral.data\nDataUnits: (photons) m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"charge_exchange.channel[:].spectrum[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].slit_width\nWidth of the slit (placed in the object focal plane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].spectrum[:].wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].t_i_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].t_i_average_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff.data\nDataData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].zeff.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average.data\nDataData Type: FLT_1D\nCoordinates: [\"charge_exchange.channel[:].zeff_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_line_average_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.channel[:].zeff_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"charge_exchange.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue\nEtendue (geometric extent) of the optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: charge_exchange.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].conductor[:].elements.intermediate_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].conductor[:].elements.types\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].conductor[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].conductor[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"coils_non_axisymmetric.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: coils_non_axisymmetric.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"controllers.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].data\nArray of scalar metrics in time Data Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.controllability_metrics[:].time\nControlability metric timeUnits: s\nData Type: FLT_1D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].controller_class\nOne of a known class of controllersData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].description\nDescription of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].input_names\nNames of the input signals, following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].inputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.linear_controller[:].inputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].inputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].name\nName of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].output_names\nNames of the output signals following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].outputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.linear_controller[:].outputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].outputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.d.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.d.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.d.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.i.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.i.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.i.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.p.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].pid.p.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.p.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.tau.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"controllers.linear_controller[:].pid.tau.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].pid.tau.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.a.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].statespace.a.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.a.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.b.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].input_names\", \"controllers.linear_controller[:].statespace.b.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.b.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.c.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].statespace.c.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.c.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.d.data\nDataUnits: mixed\nData Type: FLT_3D\nCoordinates: [\"controllers.linear_controller[:].statespace.state_names\", \"controllers.linear_controller[:].output_names\", \"controllers.linear_controller[:].statespace.d.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.d.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.deltat.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"controllers.linear_controller[:].statespace.deltat.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.deltat.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.linear_controller[:].statespace.state_names\nNames of the statesData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].controller_class\nOne of a known class of controllersData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].description\nDescription of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].function\nMethod to be definedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].input_names\nNames of the input signals, following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].inputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.nonlinear_controller[:].inputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].inputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].name\nName of this controllerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].output_names\nOutput signal names following the SDN conventionData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].outputs.data\nDataUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"controllers.nonlinear_controller[:].outputs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.nonlinear_controller[:].outputs.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: controllers.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.change[:].profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_instant_changes.change[:].profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_instant_changes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_instant_changes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_instant_changes.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.data\nCovariance matrixUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"core_profiles.covariance.rows_uri\", \"core_profiles.covariance.rows_uri\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.description\nDescription of this covariance matrixData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.covariance.rows_uri\nList of URIs corresponding to the rows (1st dimension) of the covariance matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector it is sufficient to give a single URI where this vector is denoted using the (:) implicit notation, e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_pol\nPoloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_tor\nToroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.beta_tor_norm\nNormalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA] Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_bootstrap\nBootstrap current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_non_inductive\nTotal non-inductive current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.current_ohmic\nOhmic current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ejima\nEjima coefficient : resistive psi losses divided by (mu0RIp). See S. Ejima et al, Nuclear Fusion, Vol.22, No.10 (1982), 1313Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.energy_diamagnetic\nPlasma energy content = 3/2 * integral over the plasma volume of the total perpendicular pressure Units: J\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion[:].n_i_volume_average\nVolume averaged density of this ion species (averaged over the plasma volume up to the LCFS)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion[:].t_i_volume_average\nVolume averaged temperature of this ion species (averaged over the plasma volume up to the LCFS)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ion_time_slice\nTime slice of the profiles1d array used to define the ion composition of the globalquantities/ion array.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.ip\nTotal plasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.li_3\nInternal inductance. The li3 definition is used, i.e. li3 = 2/R0/mu0^2/Ip^2 * int(Bp^2 dV).Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.n_e_volume_average\nVolume averaged electron density (average over the plasma volume up to the LCFS)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.polarized_fuel_fraction\nN/AData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.resistive_psi_losses\nResistive part of the poloidal flux losses, defined as the volume-averaged scalar product of the electric field and the ohmic current density, normalized by the plasma current and integrated in time from the beginning of the plasma discharge: int ( (int(Efieldtor.johmtor) dV) / Ip ) dt)Units: Wb\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_e_peaking\nElectron temperature peaking factor, defined as the Te value at the magnetic axis divided by the volume averaged Te (average over the plasma volume up to the LCFS)Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_e_volume_average\nVolume averaged electron temperature (average over the plasma volume up to the LCFS)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.t_i_average_peaking\nIon temperature (averaged over ion species and states) peaking factor, defined as the Ti value at the magnetic axis divided by the volume averaged Ti (average over the plasma volume up to the LCFS)Data Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.v_loop\nLCFS loop voltage (positive value drives positive ohmic current that flows anti-clockwise when viewed from above)Units: V\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.global_quantities.z_eff_resistive\nVolume average plasma effective charge, estimated from the flux consumption in the ohmic phaseData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.psi_norm\nNormalized poloidal magnetic fluxData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure\nTotal pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"core_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].ion_index\nIndex of the corresponding ion species in the ../../../profiles_1d/ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz’+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(x_z) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].t_i_average\nIon temperature (averaged on states and ion species)Units: eV\nData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.profiles_2d[:].zeff\nEffective chargeData Type: FLT_2D\nCoordinates: [\"core_profiles.profiles_2d[:].grid.dim1\", \"core_profiles.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics valueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path\nFor Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3) Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].quantity_2d[:].statistics_type[:].value\nValue of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].time_width\nWidth of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.statistics[:].uq_input_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_profiles.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"core_sources.source[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].current_parallel\nParallel current drivenUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].electrons.particles\nElectron particle sourceUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].electrons.power\nPower coupled to electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].power\nTotal power coupled to the plasmaUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].torque_tor\nToroidal torqueUnits: kg.m^2.s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].total_ion_particles\nTotal ion particle source (summed over ion species)Units: (ions).s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].global_quantities[:].total_ion_power\nTotal power coupled to ion species (summed over ion species)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].conductivity_parallel\nParallel conductivity due to this sourceUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_parallelUnits: A\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy\nSource term for the electron energy equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles\nSource term for electron density equationUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.particles_inside\nElectron source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].electrons.power_inside\nPower coupled to electrons inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.psi_norm\nNormalized poloidal magnetic fluxData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy\nSource term for the ion energy transport equation.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].fast_particles_energy\nIncoming energy of the fast ion particles (eg. fusion 3.5MeV alphas or 1MeV nbi)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.diamagnetic\nDiamagnetic componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.parallel\nParallel componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.poloidal\nPoloidal componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.radial\nRadial componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal\nToroidal componentUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.explicit_part\nExplicit part of the source termUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].momentum.toroidal_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles\nSource term for ion density equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].particles_inside\nIon source inside the flux surface. Cumulative volume integral of the source term for the ion density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].power_inside\nPower coupled to the ion species inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy\nSource terms for the charge state energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles\nSource term for the charge state density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.explicit_part\nExplicit part of the source termUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].particles_inside\nState source inside the flux surface. Cumulative volume integral of the source term for the electron density equation.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].power_inside\nPower coupled to the state inside the flux surface. Cumulative volume integral of the source term for the electron energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].j_parallel\nParallel current density source, average(J.B) / B0, where B0 = coresources/vacuumtoroidal_field/b0 Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].momentum_tor\nSource term for total toroidal momentum equationUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].momentum_tor_j_cross_b_field\nContribution to the toroidal momentum source term (already included in the momentum_tor node) corresponding to the toroidal torques onto the thermal plasma due to Lorentz force associated with radial currents. These currents appear as return-currents (enforcing quasi-neutrality, div(J)=0) balancing radial currents of non-thermal particles, e.g. radial currents of fast and trapped neutral-beam-ions.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].energy\nSource term for the neutral energy transport equation.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].particles\nSource term for neutral density equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].energy\nSource terms for the state energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].particles\nSource term for the state density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].torque_tor_inside\nToroidal torque inside the flux surface. Cumulative volume integral of the source term for the total toroidal momentum equationUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy\nSource term for the total (summed over ion species) energy equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.explicit_part\nExplicit part of the source termUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_energy_decomposed.implicit_part\nImplicit part of the source term, i.e. to be multiplied by the equation's primary quantityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].profiles_1d[:].total_ion_power_inside\nTotal power coupled to ion species (summed over ion species) inside the flux surface. Cumulative volume integral of the source term for the total ion energy equationUnits: W\nData Type: FLT_1D\nCoordinates: [\"core_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_sources.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"core_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"core_transport.model[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].comment\nAny comment describing the modelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].flux_multiplier\nMultiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].e_field_radial\nRadial component of the electric field (calculated e.g. by a neoclassical model)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].electrons.particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_d.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_flux.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].grid_v.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.diamagnetic.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.parallel.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.poloidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.radial.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].momentum.toroidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.diamagnetic.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.parallel.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.poloidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.radial.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flow_damping_rate\nDamping rate for this flow component (e.g. due to collisions, calculated from a neoclassical model)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].momentum.toroidal.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.flux\nFluxUnits: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].momentum_tor.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].particles.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_d.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.flux\nFluxUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_flux.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.model[:].profiles_1d[:].total_ion_energy.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"core_transport.model[:].profiles_1d[:].grid_v.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"core_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: core_transport.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.availability\nAvailability fraction of the plantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.construction_start_year\nYear that plant construction beginsUnits: year\nData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.cost\nCost to decomission the plantUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].cost\nCost to decommission the systemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].name\nName of the system to decommissionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].subsystem[:].cost\nCost to decommission the subsystemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_decommissioning.system[:].subsystem[:].name\nName of the subsystem to decommissionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.cost\nTotal direct capitalUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].cost\nCost of the systemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].subsystem[:].cost\nCost of the subsystemUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_direct_capital.system[:].subsystem[:].name\nName of the subsystemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_lifetime\nTotal cost of fusion power plantUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].name\nName of the systemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].subsystem[:].name\nName of the subsystemData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].subsystem[:].yearly_cost\nCost of the subsystem per yearUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.system[:].yearly_cost\nCost of system per yearUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.cost_operations.yearly_cost\nAnual cost to operate the plantUnits: $M/year\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.inflation_rate\nPredicted average rate of future inflationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.learning.hts.learning_rate\nLearning rate for ReBCO technology productionData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.future.learning.hts.production_increase\nFactor by which production of ReBCO multipliesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.levelized_CoE\nLevelized cost of electiricity (total cost / total electricy generated)Units: $/kWh\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.plant_lifetime\nLifetime of the plantUnits: year\nData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: costing.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"cryostat.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].cryostat.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].cryostat.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"cryostat.description_2d[:].thermal_shield.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.description_2d[:].thermal_shield.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: cryostat.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.dd_version\nVersion of the physics data dictionary of this datasetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.imas_version\nVersion of the IMAS infrastructure used to produce this data entry. Refers to the global IMAS repository which links to versions of every infrastructure toolsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.parent_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin\nDate and time (UTC) at which the pulse started on the experiment, expressed in a human readable form (ISO 8601) : the format of the string shall be : YYYY-MM-DDTHH:MM:SSZ. Example : 2020-07-24T14:19:00ZData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin_epoch.nanoseconds\nElapsed nanoseconds since the time in seconds indicated aboveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_begin_epoch.seconds\nElapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_end_epoch.nanoseconds\nElapsed nanoseconds since the time in seconds indicated aboveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.pulse_time_end_epoch.seconds\nElapsed seconds since the Unix Epoch time (01/01/1970 00:00:00 UTC)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.comment_after\nComment made at the end of a simulationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.comment_before\nComment made when launching a simulationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_begin\nStart timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_begun\nActual wall-clock time simulation startedUnits: UTC\nData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_current\nCurrent time of the simulationUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_end\nStop timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_ended\nActual wall-clock time simulation finishedUnits: UTC\nData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_restart\nTime of the last restart done during the simulationUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.time_step\nTime interval between main steps, e.g. storage step (if relevant and constant)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.simulation.workflow\nDescription of the workflow which has been used to produce this data entry (e.g. copy of the Kepler MOML if using Kepler)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_description.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.identifier\nPersistent identifier allowing to cite this data in a public and persistent way, should be provided as HTTP URIsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.is_referenced_by\nList of documents (e.g. publications) or datasets making use of this data entry (e.g. PIDs of other datasets using this data entry as input)Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.is_replaced_by\nPersistent identifier referencing the new version of this data (replacing the present version)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.license\nLicense(s) under which the data is made available (license description or, more convenient, publicly accessible URL pointing to the full license text)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.replaces\nPersistent identifier referencing the previous version of this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.rights_holder\nThe organisation owning or managing rights over this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: dataset_fair.valid\nDate range during which the data is or was valid. Expressed as YYYY-MM-DD/YYYY-MM-DD, where the former (resp. latter) date is the data at which the data started (resp. ceased) to be valid. If the data is still valid, the slash should still be present, i.e. indicate the validity start date with YYYY-MM-DD/. If the data ceased being valid but there is no information on the validity start date, indicate /YYYY-MM-DD.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.current_halo_pol\nPoloidal halo currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.current_halo_tor\nToroidal halo currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_ohm\nTotal ohmic cumulated energy (integral of the power over the disruption duration)Units: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_ohm_halo\nOhmic cumulated energy (integral of the power over the disruption duration) in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_parallel_halo\nCumulated parallel energy (integral of the heat flux parallel power over the disruption duration) in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_radiated_electrons_impurities\nTotal cumulated energy (integral of the power over the disruption duration) radiated by electrons on impuritiesUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.energy_radiated_electrons_impurities_halo\nCumulated energy (integral of the power over the disruption duration) radiated by electrons on impurities in the halo regionUnits: J\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_ohm\nTotal ohmic powerUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_ohm_halo\nOhmic power in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_parallel_halo\nPower of the parallel heat flux in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_radiated_electrons_impurities\nTotal power radiated by electrons on impuritiesUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.power_radiated_electrons_impurities_halo\nPower radiated by electrons on impurities in the halo regionUnits: W\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.global_quantities.psi_halo_boundary\nPoloidal flux at halo region boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].active_wall_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].active_wall_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].current_halo_pol\nPoloidal halo current crossing through this areaUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].end_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].end_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].start_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].area[:].start_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.halo_currents[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].j_runaways\nRunaways parallel current density = average(j.B) / B0, where B0 = Disruption/VacuumToroidalField/ B0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].power_density_conductive_losses\nPower density of conductive losses to the wall (positive sign for losses)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].power_density_radiative_losses\nPower density of radiative losses (positive sign for losses)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"disruption.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"disruption.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: disruption.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].discrete\nList of indices of grid spaces (refers to ../grid/space) for which the source is discretely distributed. For example consider a source of 3.5 MeV alpha particles provided on a grid with two coordinates (spaces); rho_tor and energy. To specify that the source is given at energies exactly equal to 3.5 MeV, let discret have length 1 and set discrete(1)=2 since energy is dimension number 2. The source is then proportional to delta( 1 - energy / 3.5MeV ), where delta is the direct delta distribution. Discrete dimensions can only be used when the grid is rectangular.Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distribution_sources.source[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: (m.s^-1)^-3.m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"distribution_sources.source[:].ggd[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: (m.s^-1)^-3.m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].particles\nParticle source rateUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].power\nTotal power of the sourceUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.particles\nParticle losses due to shinethroughUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.power\nPower losses due to shinethroughUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].shinethrough.torque_tor\nToroidal torque losses due to shinethroughUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].global_quantities[:].torque_tor\nTotal toroidal torque of the sourceUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"distribution_sources.source[:].markers[:].orbit_integrals.expressions\", \"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].orbit_integrals.n_tor\", \"distribution_sources.source[:].markers[:].orbit_integrals.m_pol\", \"distribution_sources.source[:].markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"distribution_sources.source[:].markers[:].orbit_integrals_instant.expressions\", \"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"distribution_sources.source[:].markers[:].weights\", \"distribution_sources.source[:].markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_beamlets_group\nIndex of the NBI beamlets group considered. Refers to the \"unit/beamlets_group\" array of the NBI IDS. 0 means sum over all beamlets groups.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].nbi_unit\nIndex of the NBI unit considered. Refers to the \"unit\" array of the NBI IDS. 0 means sum over all NBI units.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].reactant_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].process[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].energy\nSource term for the energy transport equationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].momentum_tor\nSource term for the toroidal momentum equationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].particles\nSource term for the density transport equationUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.source[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"distribution_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distribution_sources.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].expansion_fd3v[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"distributions.distribution[:].ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].temperature\nReference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)Units: eV\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_fast\nCollisional power to the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].power_thermal\nCollisional power to the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque to the fast particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque to the thermal particle populationUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].current_tor\nToroidal current driven by the distributionUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy\nTotal energy in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy_fast\nTotal energy of the fast particles in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].energy_fast_parallel\nParallel energy of the fast particles in the distributionUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].particles_fast_n\nNumber of fast particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].particles_n\nNumber of particles in the distribution, i.e. the volume integral of the density (note: this is the number of real particles and not markers)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].particles\nParticle source rateUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].power\nTotal power of the sourceUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].source[:].torque_tor\nTotal toroidal torque of the sourceUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.particles\nSource rate of thermal particles due to the thermalisation of fast particlesUnits: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.power\nPower input to the thermal particle population due to the thermalisation of fast particlesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].thermalisation.torque\nTorque input to the thermal particle population due to the thermalisation of fast particlesUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].global_quantities[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].is_delta_f\nIf isdeltaf=1, then the distribution represents the deviation from a Maxwellian; isdeltaf=0, then the distribution represents all particles, i.e. the full-f solutionData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"distributions.distribution[:].markers[:].orbit_integrals.expressions\", \"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].orbit_integrals.n_tor\", \"distributions.distribution[:].markers[:].orbit_integrals.m_pol\", \"distributions.distribution[:].markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"distributions.distribution[:].markers[:].orbit_integrals_instant.expressions\", \"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].markers[:].weights\", \"distributions.distribution[:].markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_beamlets_group\nIndex of the NBI beamlets group considered. Refers to the \"unit/beamlets_group\" array of the NBI IDS. 0 means sum over all beamlets groups.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].nbi_unit\nIndex of the NBI unit considered. Refers to the \"unit\" array of the NBI IDS. 0 means sum over all NBI units.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].reactant_energy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].process[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].co_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].counter_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.energy\nEnergy at which the fast and thermal particle populations were separated, as a function of radiusUnits: eV\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].fast_filter.method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.energy\nSource rate of energy density within the thermal particle population due to the thermalisation of fast particlesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.momentum_tor\nSource rate of toroidal angular momentum density within the thermal particle population due to the thermalisation of fast particlesUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].thermalisation.particles\nSource rate of thermal particle density due to the thermalisation of fast particlesUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].energy\nSource rate of energy densityUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.process_index\nIndex into distribution/processData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].identifier.wave_index\nIndex into distribution/waveData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].momentum_tor\nSource rate of toroidal angular momentum density Units: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.source[:].particles\nSource rate of thermal particle densityUnits: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_1d[:].trapped.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].co_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].counter_passing.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.rho_tor\nToroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.theta_geometric\nGeometrical poloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.theta_straight\nStraight field line poloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.electrons.torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_fast\nCollisional power density to the fast particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].power_thermal\nCollisional power density to the thermal particle populationUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_fast_tor\nCollisional toroidal torque density to the fast particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].torque_thermal_tor\nCollisional toroidal torque density to the thermal particle populationUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.collisions.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.current_fast_tor\nTotal toroidal driven current density of fast (non-thermal) particles (excluding electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.current_tor\nTotal toroidal driven current density (including electron and thermal ion back-current, or drag-current)Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.density_fast\nDensity of fast particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure\nPressure (thermal+non-thermal)Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure_fast\nPressure of fast particlesUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.pressure_fast_parallel\nPressure of fast particles in the parallel directionUnits: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].profiles_2d[:].trapped.torque_tor_j_radial\nToroidal torque due to radial currentsUnits: N.m^-2\nData Type: FLT_2D\nCoordinates: [\"distributions.distribution[:].profiles_2d[:].grid.r\", \"distributions.distribution[:].profiles_2d[:].grid.z\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].antenna_name\nName of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].index_in_antenna\nIndex of the wave (starts at 1), separating different waves generated from a single antenna.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.distribution[:].wave[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"distributions.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: distributions.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"divertors.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].identifier\nAlphanumeric identifier of divertorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].name\nName of the divertorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].particle_flux_recycled_total.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].particle_flux_recycled_total.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].particle_flux_recycled_total.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_black_body.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_black_body.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_black_body.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_conducted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_conducted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_conducted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_convected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_convected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_convected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_currents.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_currents.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_currents.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_incident.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_radiated.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_radiated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_radiated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_recombination_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_plasma.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_recombination_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_recombination_plasma.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_thermal_extracted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].power_thermal_extracted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].power_thermal_extracted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].extension_r\nTarget length projected on the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].extension_z\nTarget length projected on the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].flux_expansion.data\nDataData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].flux_expansion.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].flux_expansion.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].heat_flux_steady_limit_max\nMaximum steady state heat flux allowed on divertor target surface (engineering design limit)Units: W.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].identifier\nAlphanumeric identifier of targetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].name\nName of the targetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_black_body.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_black_body.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_black_body.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_conducted.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_conducted.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_conducted.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_convected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_convected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_convected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_currents.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_currents.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_currents.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_flux_peak.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_flux_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_flux_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident_fraction.data\nDataData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_incident_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_incident_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_radiated.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_radiated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_radiated.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_neutrals.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_recombination_neutrals.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_neutrals.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_plasma.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].power_recombination_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].power_recombination_plasma.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].t_e_target_sputtering_limit_max\nMaximum plasma temperature allowed on the divertor target to avoid excessive sputteringUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].temperature_limit_max\nMaximum surface target temperature allowed to prevent damage (melting, recrystallization, sublimation, etc...)Units: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].current_incident.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].current_incident.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].current_incident.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].identifier\nAlphanumeric identifier of tileData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].name\nName of the tileData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].shunt_index\nIf the tile carries a measurement shunt, index of that shunt (in the magnetics IDS shunt array)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_area\nArea of the tile surface facing the plasmaUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].surface_outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tile[:].surface_outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tile[:].surface_outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_pol.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tilt_angle_pol.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_pol.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_tor.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].tilt_angle_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].tilt_angle_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].n_e_target\nElectron density at divertor targetUnits: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].sol_heat_decay_length\nHeat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].sol_heat_spreading_length\nHeat flux spreading length in SOL at equatorial mid-plane, this is the S power spreading parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031. Relevant only for attached plasmas.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].t_e_target\nElectron temperature at divertor targetUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].two_point_model[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].wetted_area.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].target[:].wetted_area.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].target[:].wetted_area.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].wetted_area.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"divertors.divertor[:].wetted_area.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.divertor[:].wetted_area.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: divertors.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].identifier\nBeam identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r_limit_max\nMajor radius upper limit for the systemUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.r_limit_min\nMajor radius lower limit for the systemUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].launching_position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].mode\nIdentifier for the main plasma wave mode excited by the EC beam. For the ordinary mode (O-mode), mode=1. For the extraordinary mode (X-mode), mode=-1Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].name\nBeam nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].o_mode_fraction\nFraction of EC beam power launched in ordinary (O) mode. If all power is launched in ordinary mode (O-mode), omodefraction = 1.0. If all power is launched in extraordinary mode (X-mode), omodefraction = 0.0Data Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].phase.angle\nRotation angle for the phase ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].phase.curvature\nInverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)Units: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].spot.angle\nRotation angle for the spot ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].spot.size\nSize of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].steering_angle_pol\nSteering angle of the EC beam in the R,Z plane (from the -R axis towards the -Z axis), anglepol=atan2(-kZ,-kR), where kZ and k_R are the Z and R components of the mean wave vector in the EC beamUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].steering_angle_tor\nSteering angle of the EC beam away from the poloidal plane that is increasing towards the positive phi axis, angletor=arcsin(kphi/k), where k_phi is the component of the wave vector in the phi direction and k is the length of the wave vector. Here the term wave vector refers to the mean wave vector in the EC beamUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ec_launchers.beam[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.beam[:].time\nTime base used for launchingposition, omode_fraction, angle, spot and phase quantitiesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ec_launchers.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ec_launchers.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].beam.phase.angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.curvature.data\nDataUnits: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"ece.channel[:].beam.phase.curvature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.phase.curvature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].beam.spot.angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.size.data\nDataUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"ece.channel[:].beam.spot.size.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].beam.spot.size.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].delta_position_suprathermal.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].frequency.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.data\nDataData Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].harmonic.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].if_bandwidth\nFull-width of the Intermediate Frequency (IF) bandpass filterUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.data\nDataData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].optical_depth.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"ece.channel[:].t_e_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].t_e_voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.channel[:].t_e_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.channel[:].time\nTimebase for the processed dynamic data of this channel (outside of the beam structure)Units: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ece.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].polarization_angle\nAlignment angle of the polarizer in the (x1,x2) plane. Electric fields parallel to the polarizer angle will be reflected. The angle is defined with respect to the x1 unit vector, positive in the counter-clockwise direction when looking towards the plasmaUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.polarizer[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"ece.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"ece.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.rho_tor_norm\nNormalised toroidal flux coordinate of the measurementData Type: FLT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.t_e_central.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"ece.t_e_central.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ece.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].a_field_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].a_field_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].e_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].electrons.temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].electrons.velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].ionisation_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].velocity_exb[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].z_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_average[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Elementary Charge Unit\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].state[:].z_square_average[:].values\nOne scalar value is provided per element in the grid subset.Units: Elementary Charge Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].ion[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_anomalous[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_heat_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_inertial[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_ion_neutral_friction[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].j_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_parallel_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_perpendicular_viscosity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_pfirsch_schlueter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].j_total[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].n_i_total_over_n_e[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].n_i_total_over_n_e[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].density_fast[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].distribution_function[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].pressure_fast_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_diamagnetic[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].velocity_exb[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].neutral[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].neutral[:].velocity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Pa\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].pressure_thermal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].pressure_thermal[:].values\nOne scalar value is provided per element in the grid subset.Units: Pa\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].t_i_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].t_i_average[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_profiles.ggd[:].zeff[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd[:].zeff[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.density[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].electrons.temperature[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].energy_thermal[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].content[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].density[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].temperature[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_profiles.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].current_parallel_inside\nParallel current driven inside the flux surface. Cumulative surface integral of j_totalUnits: A\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.diamagnetic\nDiamagnetic componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.parallel\nParallel componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.poloidal\nPoloidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.radial\nRadial componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].e_field.toroidal\nToroidal componentUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.collisionality_norm\nCollisionality normalised to the bounce frequencyData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].electrons.temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].electrons.temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].density_validity\nIndicator of the validity of the density profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken) (average over charge states when multiple charge states are considered)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\nMeasured valuesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.reconstructed\nValue reconstructed from the fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].state[:].density_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].ionisation_potential\nCumulative and average ionisation potential to reach a given bundle. Defined as sum (xz* (sum of Epot from z'=0 to z-1)), where Epot is the ionisation potential of ion Xz+, and xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].rotation_frequency_tor\nToroidal rotation frequency (i.e. toroidal velocity divided by the major radius at which the toroidal velocity is taken)Units: rad.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average\nAverage Z of the charge state bundle, volume averaged over the plasma radius (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average_1d\nAverage charge profile of the charge state bundle (equal to zmin if no bundle), = sum (Z*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_average_square_1d\nAverage square charge profile of the charge state bundle (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].state[:].z_square_average\nAverage Z square of the charge state bundle, volume averaged over the plasma radius (equal to zmin squared if no bundle), = sum (Z^2*xz) where xz is the relative concentration of a given charge state in the bundle, i.e. sum(xz) = 1 over the bundle.Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].ion[:].temperature_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].temperature_validity\nIndicator of the validity of the temperature profile. 0: valid from automated processing, 1: valid and certified by the RO; - 1 means problem identified in the data processing (request verification by the RO), -2: invalid data, should not be usedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.diamagnetic\nDiamagnetic componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.parallel\nParallel componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.poloidal\nPoloidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.radial\nRadial componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].velocity.toroidal\nToroidal componentUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion_1d\nAverage charge of the ion species (sum of states charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].ion[:].z_ion_square_1d\nAverage square charge of the ion species (sum of states square charge weighted by state density and divided by ion density)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = edgeprofiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = edgeprofiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons weighted by their density and major radius, i.e. sumoverspecies(nRm*Vphi)Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].n_i_thermal_total\nTotal ion thermal density (sum over species and charge states)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].label\nString identifying the species (e.g. H, D, T, He, C, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure\nPressure (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2) (sum over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure\nPressure (thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_parallel\nFast (non-thermal) parallel pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].pressure_thermal\nPressure (thermal) associated with random motion ~average((v-average(v))^2)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].phi_potential\nElectrostatic potential, averaged on the magnetic flux surfaceUnits: V\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_ion_total\nTotal (sum over ion species) thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].q\nSafety factorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].rotation_frequency_tor_sonic\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.measured\nMeasured valuesUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.reconstructed\nValue reconstructed from the fitUnits: eV\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].t_i_average_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].t_i_average_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].grid.rho_pol_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.chi_squared\nSquared error normalized by the weighted standard deviation considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.local\nInteger flag : 1 means local measurement, 0 means line-integrated measurementData Type: INT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.measured\nMeasured valuesData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.parameters\nList of the fit specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.reconstructed\nValue reconstructed from the fitData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.rho_pol_norm\nNormalised poloidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.rho_tor_norm\nNormalised toroidal flux coordinate of each measurement (local value for a local measurement, minimum value reached by the line of sight for a line measurement)Data Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.source\nPath to the source data for each measurement in the IMAS data dictionary, e.g. ece/channel(i)/t_e for the electron temperature on the i-th channel in the ECE IDSData Type: STR_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement\nExact time slices used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_slice_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.time_measurement_width\nIn case the measurements are averaged over a time interval, this node is the full width of this time interval (empty otherwise). In case the slicing/averaging method doesn't use a hard time interval cutoff, this width is the characteristic time span of the slicing/averaging method. By convention, the time interval starts at timemeasurement-timewidth and ends at time_measurement.Units: s\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.profiles_1d[:].zeff_fit.weight\nWeight given to each measured valueData Type: FLT_1D\nCoordinates: [\"edge_profiles.profiles_1d[:].zeff_fit.measured\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the grid used to represent the statistics valueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].grid_subset_index\nOnly if the statistics value is given on a different GGD grid subset than the original quantity (e.g. if the statistics has worked over a dimension of the GGD), index of the new grid subset the statistics value is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].uq_input_path\nFor Sobol index only, path to the related the uqinput quantity, e.g. ../../../uqinput_2d(3) Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].quantity_2d[:].statistics_type[:].value\nValue of the statistics for that quantity, the array corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].time_width\nWidth of the time interval over which the statistics have been calculated. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].distribution.bins\nBins of quantitiy values, defined for each element (first dimension) corresponding to the first dimension of the original 2D quantityUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].distribution.probability\nProbability to have a value of the quantity between bins(n) and bins(n+1) (thus the size of its second dimension is the size of the second dimension of the bins array - 1). The first dimension correspond to the first dimension of the original 2D quantityData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.statistics[:].uq_input_2d[:].path\nPath of the quantity within the IDS, following the syntax given in the link belowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"edge_profiles.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_profiles.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_sources.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_sources.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].current[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].current[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].electrons.energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].electrons.particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].electrons.particles[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].momentum[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].particles[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"edge_sources.source[:].ggd[:].total_ion_energy[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd[:].total_ion_energy[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.label\nString identifying ion state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.state.z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.ion.z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.label\nString identifying neutral state Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.neutral.state.vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.source[:].species.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_sources.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"edge_transport.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"edge_transport.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.output_flag.data\nDataData Type: INT_1D\nCoordinates: [\"edge_transport.model[:].code.output_flag.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.output_flag.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].flux_multiplier\nMultiplier applied to the particule flux when adding its contribution in the expression of the heat flux : can be 0, 3/2 or 5/2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].conductivity[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: ohm^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].electrons.particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].label\nString identifying state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_limiter[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic\nDiamagnetic component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].diamagnetic_coefficients\nInterpolation coefficients for the diamagnetic component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel\nParallel component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].parallel_coefficients\nInterpolation coefficients for the parallel component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal\nPoloidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].poloidal_coefficients\nInterpolation coefficients for the poloidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial\nRadial component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].radial_coefficients\nInterpolation coefficients for the radial component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].momentum.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].particles.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.d_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_limiter[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.flux_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_pol[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd[:].total_ion_energy.v_radial[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].electrons.power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].energy_flux_max[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].neutral[:].particle_flux_integrated[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].power_ion_total[:].value\nScalar value of the quantity on the grid subset (corresponding to a single local position or to an integrated value over the subset)Units: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].ggd_fast[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: edge_transport.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.active_coils\nList of URIs of the active coils considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_active.coil\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes\nList of URIs of the poloidal field probes considered in the IDSData Type: STR_1D\nCoordinates: [\"magnetics.b_field_pol_probe\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_active\nPoloidal field coupling from active coils to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"magnetics.b_field_pol_probe\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_passive\nPoloidal field coupling from passive loops to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"em_coupling.b_field_pol_probes\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.b_field_pol_probes_plasma\nPoloidal field coupling from plasma elements to poloidal field probesUnits: T/A\nData Type: FLT_2D\nCoordinates: [\"em_coupling.b_field_pol_probes\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"em_coupling.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].columns_uri\nList of URIs corresponding to the columns (2nd dimension) of the coupling matrix. See examples above (rows_uri)Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].data\nCoupling matrixUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"em_coupling.coupling_matrix[:].rows_uri\", \"em_coupling.coupling_matrix[:].columns_uri\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].name\nName of this coupling matrixData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].quantity.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.coupling_matrix[:].rows_uri\nList of URIs corresponding to the rows (1st dimension) of the coupling matrix. If not all indices of a given node are used, they must be listed explicitly e.g. rowsuri(i) = pfactive:1/coil(i) will refer to a list of indices of the occurrence 1 of the pfactive IDS of this data entry. If the rows correspond to all indices of a given vector, it is sufficient to give a insgle uri, the one of the vector with the impliicit notation (:), e.g. rowsuri(1) = /gridggd(3)/gridsubset(2)/elements(:).Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.flux_loops\nList of URIs of the flux loops considered in the IDSData Type: STR_1D\nCoordinates: [\"magnetics.flux_loop\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"em_coupling.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_active_active\nMutual inductance coupling from active coils to active coilsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.active_coils\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_active\nMutual inductance coupling from active coils to flux loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_passive\nMutual inductance coupling from passive loops to flux loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_loops_plasma\nMutual inductance from plasma elements to poloidal flux loops Units: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.flux_loops\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_passive_active\nMutual inductance coupling from active coils to passive loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.passive_loops\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_passive_passive\nMutual inductance coupling from passive loops to passive loopsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.passive_loops\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_active\nMutual inductance coupling from active coils to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.active_coils\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_passive\nMutual inductance coupling from passive loops to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.passive_loops\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.mutual_plasma_plasma\nMutual inductance coupling from plasma elements to plasma elementsUnits: H\nData Type: FLT_2D\nCoordinates: [\"em_coupling.plasma_elements\", \"em_coupling.plasma_elements\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.passive_loops\nList of URIs of the passive loops considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_passive.loop\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.plasma_elements\nList of URIs of the plasma elements considered in the IDSData Type: STR_1D\nCoordinates: [\"pf_plasma.element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: em_coupling.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"equilibrium.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"equilibrium.grids_ggd[:].grid[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].grid[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.grids_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.active_limiter_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.active_limiter_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.elongation_lower\nElongation (lower half w.r.t. geometric axis) of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.elongation_upper\nElongation (upper half w.r.t. geometric axis) of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.geometric_axis.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.geometric_axis.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.minor_radius\nMinor radius of the plasma boundary (defined as (Rmax-Rmin) / 2 of the boundary)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].boundary.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.ovality\nOvality of the plasma boundary [MXH c1]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.psi\nValue of the poloidal flux at which the boundary is takenUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.psi_norm\nValue of the normalised poloidal flux at which the boundary is taken (typically 99.x %), the flux being normalised to its value at the separatrixData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness\nSquareness of the plasma boundary [MXH -s2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_lower_inner\nLower inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_lower_outer\nLower outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_upper_inner\nUpper inner squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.squareness_upper_outer\nUpper outer squareness of the plasma boundary (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.strike_point[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.strike_point[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.tilt\nTilt of the plasma boundary [MXH c0]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity\nTriangularity of the plasma boundary [MXH sin(s1)]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity_lower\nLower triangularity of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.triangularity_upper\nUpper triangularity of the plasma boundaryData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.twist\nTwist of the plasma boundary [MXH c2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.type\n0 (limiter) or 1 (diverted)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.x_point[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary.x_point[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary_secondary_separatrix.distance_inner_outer\nDistance between the inner and outer separatrices, in the major radius direction, at the plasma outboard and at the height corresponding to the maximum R for the inner separatrix.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].boundary_secondary_separatrix.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.b_field_tor_vacuum_r.source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.flux_loop[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.ip.chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.ip.measured\nMeasured valueUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.measured\nMeasured valueUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.reconstructed\nValue calculated from the reconstructed equilibriumUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.iron_core_segment[:].magnetisation_z.source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].measured\nMeasured valueUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_parallel[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].measured\nMeasured valueUnits: A.m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.j_tor[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.mse_polarisation_angle[:].measured\nMeasured valueUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].measured\nMeasured valueUnits: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.n_e[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pf_passive_current[:].measured\nMeasured valueUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pf_passive_current[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].measured\nMeasured valueUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].measured\nMeasured valueUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.pressure_rotational[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].chi_squared\nSquared error normalized by the variance considered in the minimization process : chi_squared = weight^2 *(reconstructed - measured)^2 / sigma^2, where sigma is the standard deviation of the measurement errorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].measured\nMeasured valueData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].reconstructed\nValue calculated from the reconstructed equilibriumData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.q[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_r\nSquared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].chi_squared_z\nSquared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_measured.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_measured.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].position_reconstructed.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.strike_point[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].chi_squared_r\nSquared error on the major radius normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/r - position_measured/r)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].chi_squared_z\nSquared error on the altitude normalized by the variance considered in the minimization process : chisquared = weight^2 *(positionreconstructed/z - position_measured/z)^2 / sigma^2, where sigma is the standard deviation of the measurement errorUnits: m^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].exact\nInteger flag : 1 means exact data, taken as an exact input without being fitted; 0 means the equilibrium code does a least square fitData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_measured.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_measured.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].position_reconstructed.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].source\nPath to the source data for this measurement in the IMAS data dictionaryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].time_measurement\nExact time slice used from the time array of the measurement source data. If the time slice does not exist in the time array of the source data, it means linear interpolation has been usedUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].constraints.x_point[:].weight\nWeight given to the measurementData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_expression.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.grad_shafranov_deviation_value\nValue of the residual deviation between the left and right hand side of the Grad Shafranov equation, evaluated as per gradshafranovdeviation_expressionUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].convergence.result.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].coordinate_system.grid.dim1\", \"equilibrium.time_slice[:].coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].j_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].j_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].j_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].phi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].phi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].r[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: rad\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].theta[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].theta[:].values\nOne scalar value is provided per element in the grid subset.Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].ggd[:].z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].ggd[:].z[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.area\nArea of the LCFS poloidal cross sectionUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_normal\nNormalised toroidal beta, defined as 100 * beta_tor * a[m] * B0 [T] / ip [MA] Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_pol\nPoloidal beta. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.beta_tor\nToroidal beta, defined as the volume-averaged total perpendicular pressure divided by (B0^2/(2*mu0)), i.e. beta_toroidal = 2 mu0 int(p dV) / V / B0^2Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.r\nMajor radius of the current center, defined as integral over the poloidal cross section of (j_torrdS) / IpUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.velocity_z\nVertical velocity of the current centerUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.current_centre.z\nHeight of the current center, defined as integral over the poloidal cross section of (j_torzdS) / IpUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.energy_mhd\nPlasma energy content = 3/2 * int(p,dV) with p being the total pressure (thermal + fast particles) [J]. Time-dependent; ScalarUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.ip\nPlasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Units: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.length_pol\nPoloidal length of the magnetic surfaceUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.li_3\nInternal inductanceData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.b_field_tor\nTotal toroidal magnetic field at the magnetic axisUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.r\nMajor radius of the magnetic axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.magnetic_axis.z\nHeight of the magnetic axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.plasma_inductance\nPlasma inductance 2 Emagnetic/Ip^2, where Emagnetic = 1/2 * int(psi.j_tor.dS) (integral over the plasma poloidal cross-section)Units: H\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.plasma_resistance\nPlasma resistance = int(e_field.j.dV) / Ip^2Units: ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_axis\nPoloidal flux at the magnetic axisUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_boundary\nPoloidal flux at the selected plasma boundary Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.psi_external_average\nAverage (over the plasma poloidal cross section) plasma poloidal magnetic flux produced by all external circuits (CS and PF coils, eddy currents, VS in-vessel coils), given by the following formula : int(psiexternal.jtor.dS) / IpUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_95\nq at the 95% poloidal flux surface (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_axis\nq at the magnetic axisData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.psi\nMinimum q position in poloidal fluxUnits: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.psi_norm\nMinimum q position in normalised poloidal fluxData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.rho_tor_norm\nMinimum q position in normalised toroidal flux coordinateData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.q_min.value\nMinimum q valueData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.rho_tor_boundary\nToroidal flux coordinate at the selected plasma boundaryUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.v_external\nExternal voltage, i.e. time derivative of psiexternalaverage (with a minus sign : - dpsiexternalaverage/dtime)Units: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].global_quantities.volume\nTotal plasma volumeUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_average\nFlux surface averaged modulus of B (always positive, irrespective of the sign convention for the B-field direction).Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_max\nMaximum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.b_field_min\nMinimum(modulus(B)) on the flux surface (always positive, irrespective of the sign convention for the B-field direction)Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.beta_pol\nPoloidal beta profile. Defined as betap = 4 int(p dV) / [R0 * mu0 * Ip^2]Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.darea_dpsi\nRadial derivative of the cross-sectional area of the flux surface with respect to psiUnits: m^2.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.darea_drho_tor\nRadial derivative of the cross-sectional area of the flux surface with respect to rho_torUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dpressure_dpsi\nDerivative of pressure w.r.t. psiUnits: Pa.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dpsi_drho_tor\nDerivative of Psi with respect to Rho_TorUnits: Wb/m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dvolume_dpsi\nRadial derivative of the volume enclosed in the flux surface with respect to PsiUnits: m^3.Wb^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.dvolume_drho_tor\nRadial derivative of the volume enclosed in the flux surface with respect to Rho_TorUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.elongation\nElongationData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.f\nDiamagnetic function (F=R B_Phi)Units: T.m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.f_df_dpsi\nDerivative of F w.r.t. Psi, multiplied with FUnits: T^2.m^2/Wb\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.fsa_bp\nFlux surface averaged BpUnits: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.geometric_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.geometric_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm1\nFlux surface averaged 1/R^2Units: m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm10\nFlux surface averaged R^2Units: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm2\nFlux surface averaged |gradrhotor|^2/R^2Units: m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm3\nFlux surface averaged |gradrhotor|^2Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm4\nFlux surface averaged 1/B^2Units: T^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm5\nFlux surface averaged B^2Units: T^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm6\nFlux surface averaged |gradrhotor|^2/B^2Units: T^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm7\nFlux surface averaged |gradrhotor|Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm8\nFlux surface averaged RUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.gm9\nFlux surface averaged 1/RUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.j_parallel\nFlux surface averaged approximation to parallel current density = average(j.B) / B0, where B0 = /vacuumtoroidalfield/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.j_tor\nFlux surface averaged toroidal current density = average(j_tor/R) / average(1/R)Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.mass_density\nMass densityUnits: kg.m^-3\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.phi\nToroidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.psi\nPoloidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.psi_norm\nNormalised poloidal flux coordinateData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.q\nSafety factor (IMAS uses COCOS=11: only positive when toroidal current and magnetic field are in same direction)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.r_inboard\nRadial coordinate (major radius) on the inboard side of the magnetic axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.r_outboard\nRadial coordinate (major radius) on the outboard side of the magnetic axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_tor\nToroidal flux coordinate = sqrt(phi/(pi*b0)), where the toroidal flux, phi, corresponds to timeslice/profiles1d/phi, the toroidal magnetic field, b0, corresponds to vacuumtoroidalfield/b0 and pi can be found in the IMAS constantsUnits: m\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.rho_volume_norm\nNormalised square root of enclosed volume (radial coordinate). The normalizing value is the enclosed volume at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_lower_inner\nLower inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_lower_outer\nLower outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_upper_inner\nUpper inner squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.squareness_upper_outer\nUpper outer squareness (definition from T. Luce, Plasma Phys. Control. Fusion 55 (2013) 095009)Data Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.trapped_fraction\nTrapped particle fractionData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.triangularity_lower\nLower triangularity w.r.t. magnetic axisData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.triangularity_upper\nUpper triangularity w.r.t. magnetic axisData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_1d.volume\nVolume enclosed in the flux surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time_slice[:].profiles_1d.psi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_r\nR component of the poloidal magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_tor\nToroidal component of the magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].b_field_z\nZ component of the poloidal magnetic fieldUnits: T\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].j_parallel\nDefined as (j.B)/B0 where j and B are the current density and magnetic field vectors and B0 is the (signed) vacuum toroidal magnetic field strength at the geometric reference point (R0,Z0). It is formally not the component of the plasma current density parallel to the magnetic fieldUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].j_tor\nToroidal plasma current densityUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].phi\nToroidal fluxUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].psi\nValues of the poloidal flux at the grid in the poloidal planeUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].theta\nValues of the poloidal angle on the gridUnits: rad\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].profiles_2d[:].z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"equilibrium.time_slice[:].profiles_2d[:].grid.dim1\", \"equilibrium.time_slice[:].profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"equilibrium.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: equilibrium.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ferritic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].dimension\nSpace dimension of the grid subset elements. This must be equal to the sum of the dimensions of the individual objects forming the element.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].dimension\nDimension of the objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"ferritic.grid_ggd.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object may have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object. Its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.grid_ggd.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].axisymmetric[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].axisymmetric[:].thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.x\nList of X coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.y\nList of Y coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].centroid.z\nList of Z coordinatesUnits: m\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].ggd_object_index\nIndex of GGD volumic object corresponding to each element. Refers to the array /gridggd/space(1)/objectsper_dimension(4)/objectData Type: INT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].permeability_table_index\nIndex of permeability table to be used for each element. If not allocated or if an element is equal to EMPTYINT, use the sibling saturated relative permeability instead ../relativepermeability, for that elementData Type: INT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].saturated_relative_permeability\nSaturated relative magnetic permeability of each elementUnits: H.m^-1\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_r\nR component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_tor\nToroidal component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].b_field_z\nZ component of the magnetic field at each centroidUnits: T\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_r\nR component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_tor\nToroidal component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].magnetic_moment_z\nZ component of the magnetic moment of each elementUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.object[:].volume\nVolume of each element of this objectUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"ferritic.object[:].centroid.x\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].b_field\nArray of magnetic field values, for each of which the relative permeability is givenUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].description\nDescription of this tableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].name\nName of this tableData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.permeability_table[:].relative_permeability\nRelative permeability as a function of the magnetic fieldData Type: FLT_1D\nCoordinates: [\"ferritic.permeability_table[:].b_field\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ferritic.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.data\nDataUnits: T\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"focs.b_field_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.b_field_z.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"focs.b_field_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"focs.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"focs.current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"focs.current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_length\nSpun fibre length on the vacuum vesselUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.beat_length\nLinear beat lengthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.id\nID of the fibre, e.g. commercial referenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.spun\nSpun periodUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.spun_initial_azimuth\nSpun fibre initial azimuthUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.twist\nTwist periodUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.fibre_properties.verdet_constant\nVerdet constantUnits: rad.T^-1.m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.id\nID of the FOCSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.name\nName of the FOCSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"focs.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"focs.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s0\nS0 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s1\nS1 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s2\nS2 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_initial.s3\nS3 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s0\nS0 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s1\nS1 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s2\nS2 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].s3\nS3 component of the unit Stokes vectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.stokes_output[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: focs.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gas_injection.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].exit_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.pipe[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].identifier\nID of the injection pipeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].length\nPipe lengthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].name\nName of the injection pipeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.pipe[:].valve_indices\nIndices (from the ../../valve array of structure) of the valve(s) that are feeding this pipeData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].electron_rate.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].electron_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].electron_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate_max\nMaximum flow rate of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].flow_rate_min\nMinimum flow rate of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].identifier\nID of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].name\nName of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].pipe_indices\nIndices (from the ../../pipe array of structure) of the pipe(s) that are fed by this valveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].response_curve.flow_rate\nFlow rate at the exit of the valveUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].response_curve.voltage\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].response_curve.voltage\nVoltage applied to open the valveUnits: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"gas_injection.valve[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_injection.valve[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gas_pumping.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_pumping.duct[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].identifier\nID of the pumping ductData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].name\nName of the pumping ductData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].flow_rate.data\nDataUnits: Pa.m^3.s^-1\nData Type: FLT_1D\nCoordinates: [\"gas_pumping.duct[:].species[:].flow_rate.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].flow_rate.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.duct[:].species[:].label\nString identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gas_pumping.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"gyrokinetics_local.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.collisions.collisionality_norm\nNormalised collisionality between two speciesData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.b_field_tor_sign\nSign of the toroidal magnetic fieldData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dc_dr_minor_norm\nDerivative of the 'c' shape coefficients with respect to rminornormData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.flux_surface.shape_coefficients_c\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.delongation_dr_minor_norm\nDerivative of the elongation with respect to rminornormData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dgeometric_axis_r_dr_minor\nDerivative of the major radius of the surface geometric axis with respect to r_minorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.dgeometric_axis_z_dr_minor\nDerivative of the height of the surface geometric axis with respect to r_minorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.ds_dr_minor_norm\nDerivative of the 's' shape coefficients with respect to rminornormData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.flux_surface.shape_coefficients_s\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.elongation\nElongationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.ip_sign\nSign of the plasma currentData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.magnetic_shear_r_minor\nMagnetic shear, defined as rminornorm/q . dq/drminornorm (different definition from the equilibrium IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.pressure_gradient_norm\nNormalised pressure gradient (derivative with respect to rminornorm)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.q\nSafety factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.r_minor_norm\nNormalised minor radius of the flux surface of interest = 1/2 * (max(R) - min(R))/L_refData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.shape_coefficients_c\n'c' coefficients in the formula defining the shape of the flux surfaceData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.flux_surface.shape_coefficients_s\n's' coefficients in the formula defining the shape of the flux surfaceData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].binormal_wavevector_norm\nNormalised binormal component of the wavevectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\nPoloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_parity\nParity of the perturbed parallel vector potential with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.a_field_parallel_perturbed_weight\nAmplitude of the perturbed parallel vector potential normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_parity\nParity of the perturbed parallel magnetic field with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.b_field_parallel_perturbed_weight\nAmplitude of the perturbed parallel magnetic field normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_parity\nParity of the perturbed electrostatic potential with respect to theta = 0 (poloidal angle)Data Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].fields.phi_potential_perturbed_weight\nAmplitude of the perturbed electrostatic potential normalised to the sum of amplitudes of all perturbed fieldsData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].frequency_norm\nFrequencyData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_norm\nGrowth rateData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].growth_rate_tolerance\nRelative tolerance on the growth rate (convergence of the simulation)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].initial_value_run\nFlag = 1 if this is an initial value run, 0 for an eigenvalue runData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].linear_weights_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_0.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_gyrocenter_bessel_1.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.density\nNormalised densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.heat_flux_parallel\nNormalised parallel heat flux (integral of 0.5 * m * v_par * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.j_parallel\nNormalised parallel current densityData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_parallel\nNormalised parallel temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.pressure_perpendicular\nNormalised perpendicular temperatureData Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_parallel_energy_perpendicular\nNormalised moment (integral over 0.5 * m * vpar * vperp^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].moments_norm_particle.v_perpendicular_square_energy\nNormalised moment (integral over 0.5 * m * v_perp^2 * v^2)Data Type: CPX_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].angle_pol\", \"gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].poloidal_turns\nNumber of poloidal turns considered in the flux-tube simulationData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].eigenmode[:].time_norm\nNormalised time of the gyrokinetic simulationData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.linear.wavevector[:].radial_wavevector_norm\nNormalised radial component of the wavevectorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.adiabatic_electrons\nFlag = 1 if electrons are adiabatic, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_energy_conservation\nFlag = 1 if the collision operator conserves energy, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_finite_larmor_radius\nFlag = 1 if finite larmor radius effects are retained in the collision operator, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_momentum_conservation\nFlag = 1 if the collision operator conserves momentum, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.collisions_pitch_only\nFlag = 1 if only pitch-angle scattering is retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_a_field_parallel\nFlag = 1 if fluctuations of the parallel vector potential are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_b_field_parallel\nFlag = 1 if fluctuations of the parallel magnetic field are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_centrifugal_effects\nFlag = 1 if centrifugal effects are retained, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_coriolis_drift\nFlag = 1 if Coriolis drift is included, 0 otherwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.model.include_full_curvature_drift\nFlag = 1 if all contributions to the curvature drift are included (including betaprime), 0 otherwise. Neglecting the betaprime contribution (Flag=0) is only recommended together with the neglect of parallel magnetic field fluctuationsData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.angle_pol\nPoloidal angle grid. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.binormal_wavevector_norm\nArray of normalised binormal wavevectorsData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_4d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_4D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_1d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_2d_surface_average.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_intensity_3d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.a_field_parallel_perturbed_norm\nNormalised perturbed parallel vector potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.b_field_parallel_perturbed_norm\nNormalised perturbed parallel magnetic fieldData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fields_zonal_2d.phi_potential_perturbed_norm\nNormalised perturbed electrostatic potentialData Type: CPX_2D\nCoordinates: [\"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_1d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_k_y_sum_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_2d_k_x_sum_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_2D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_3d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_3D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_4d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_4D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.energy_phi_potential\nContribution of the perturbed electrostatic potential to the normalised energy fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_b_field_parallel\nContribution of the perturbed parallel magnetic field to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_parallel_phi_potential\nContribution of the perturbed electrostatic potential to the parallel component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_b_field_parallel\nContribution of the perturbed parallel magnetic field to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.momentum_tor_perpendicular_phi_potential\nContribution of the perturbed electrostatic potential to the perpendicular component of the normalised toroidal momentum fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_a_field_parallel\nContribution of the perturbed parallel electromagnetic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_b_field_parallel\nContribution of the perturbed parallel magnetic field to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.fluxes_5d_rotating_frame.particles_phi_potential\nContribution of the perturbed electrostatic potential to the normalised particle fluxData Type: FLT_5D\nCoordinates: [\"gyrokinetics_local.species\", \"gyrokinetics_local.non_linear.binormal_wavevector_norm\", \"gyrokinetics_local.non_linear.radial_wavevector_norm\", \"gyrokinetics_local.non_linear.angle_pol\", \"gyrokinetics_local.non_linear.time_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.quasi_linear\nFlag = 1 if the non-linear fluxes are in fact calculated by a quasi-linear model, 0 if non-linearData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.radial_wavevector_norm\nArray of normalised radial wavevectorsData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.time_interval_norm\nNormalised time interval used to average fluxes in non-linear runsData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.non_linear.time_norm\nNormalised time of the gyrokinetic simulationData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.b_field_tor\nToroidal magnetic field at major radius rUnits: T\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.n_e\nElectron density at outboard equatorial midplane of the flux surface (angle_pol = 0)Units: m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.r\nMajor radius of the flux surface of interest, defined as (min(R)+max(R))/2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.normalizing_quantities.t_e\nElectron temperature at outboard equatorial midplane of the flux surface (angle_pol = 0)Units: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].charge_norm\nNormalised chargeData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].density_log_gradient_norm\nNormalised logarithmic gradient (with respect to rminornorm) of the densityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].density_norm\nNormalised densityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].mass_norm\nNormalised massData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].potential_energy_gradient_norm\nEffective potential energy determining the poloidal variation of the species background densityData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species_all.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].potential_energy_norm\nNormalised gradient (with respect to rminornorm) of the effective potential energyData Type: FLT_1D\nCoordinates: [\"gyrokinetics_local.species_all.angle_pol\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].temperature_log_gradient_norm\nNormalised logarithmic gradient (with respect to rminornorm) of the temperatureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].temperature_norm\nNormalised temperatureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species[:].velocity_tor_gradient_norm\nNormalised gradient (with respect to rminornorm) of the toroidal velocityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.angle_pol\nPoloidal angle grid, from -pi to pi, on which the species dependent effective potential energy (which determines the poloidal variation of the density) is expressed. The angle is defined with respect to (R0,Z0) with R0=(Rmax-Rmin)/2 and Z0=(Zmax-Zmin)/2. It is increasing clockwise. So (r,theta,phi) is right-handed. theta=0 for Z=Z0 and R>R0 (LFS)Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.beta_reference\nReference plasma beta (see detailed documentation at the root of the IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.debye_length_norm\nDebye length computed from the reference quantities (see detailed documentation at the root of the IDS)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.shearing_rate_norm\nNormalised ExB shearing rate (for non-linear runs only)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.species_all.velocity_tor_norm\nNormalised toroidal velocity of species (all species are assumed to have a purely toroidal velocity with a common toroidal angular frequency)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: gyrokinetics_local.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].filter_window[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.data\nDataUnits: (photons).s^-1.m^-2.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"hard_x_rays.channel[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.channel[:].radiance.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"hard_x_rays.channel[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"hard_x_rays.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].emissivity\nRadial profile of the plasma emissivity in this energy bandUnits: (photons).m^-3.str^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].rho_tor_norm\", \"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].half_width_external\nExternal (towards separatrix) half width of the emissivity peak (in normalised toroidal flux)Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].half_width_internal\nInternal (towards magnetic axis) half width of the emissivity peak (in normalised toroidal flux)Data Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].peak_position\nNormalised toroidal flux coordinate position at which the emissivity peaksData Type: FLT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].rho_tor_norm\nNormalised toroidal flux coordinate gridData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.emissivity_profile_1d[:].validity_timed\nIndicator of the validity of the emissivity profile data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"hard_x_rays.emissivity_profile_1d[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: hard_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.coupling\nCoupling efficiency of launched microwave power to the plasmaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].identifier\nIdentifier of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].coupling_resistance.data\nDataUnits: ohm\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].coupling_resistance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].coupling_resistance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].amplitude.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].current[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].current[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].current[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].capacitance.data\nDataUnits: F\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].capacitance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].matching_element[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].matching_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].name\nName of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_forward.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].phase_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_reflected.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].phase_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].phase_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].amplitude.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].pressure[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].identifier\nIdentifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].pressure[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].pressure[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].distance_to_conductor\nDistance to conducting wall or other conductor behind the antenna strapUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].strap[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].strap[:].width_tor\nWidth of strap in the toroidal directionUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].voltage[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].identifier\nIdentifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].name\nNameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].module[:].voltage[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].module[:].voltage[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].name\nName of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.antenna[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].m_pol\nPoloidal mode numbers, used to describe the spectrum of the antenna current. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/zData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].n_tor\nToroidal mode numbers, used to describe the spectrum of the antenna current. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].spectrum\nSpectrum of the total surface current on the antenna strap and passive components expressed in poloidal and toroidal modesUnits: A\nData Type: FLT_2D\nCoordinates: [\"ic_antennas.antenna[:].surface_current[:].m_pol\", \"ic_antennas.antenna[:].surface_current[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.antenna[:].surface_current[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ic_antennas.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"ic_antennas.power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.reference_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.reference_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ic_antennas.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\", \"interferometer.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].n_e_line_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].n_e_line_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].path_length_variation.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].path_length_variation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].path_length_variation.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].fringe_jump_correction\nSigned number of 2pi phase corrections applied to remove a fringe jump, for each time slice on which a correction has been made Data Type: INT_1D\nCoordinates: [\"interferometer.channel[:].wavelength[:].fringe_jump_correction_times\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].fringe_jump_correction_times\nList of time slices of the pulse on which a fringe jump correction has been made Units: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_corrected.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"interferometer.channel[:].wavelength[:].phase_corrected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_corrected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].phase_to_n_e_line\nConversion factor to be used to convert phase into line density for this wavelengthUnits: m^-2.rad^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.channel[:].wavelength[:].value\nWavelength valueUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"interferometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.data\nDataData Type: FLT_1D\nCoordinates: [\"interferometer.electrons_n.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.electrons_n.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.electrons_n.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"interferometer.n_e_volume_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.n_e_volume_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"interferometer.n_e_volume_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: interferometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"iron_core.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].b_field\nArray of magnetic field values, for each of which the relative permeability is givenUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].identifier\nID of the segmentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_r.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].magnetisation_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_z.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].magnetisation_z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].magnetisation_z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].name\nName of the segmentData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.segment[:].permeability_relative\nRelative permeability of the iron segmentData Type: FLT_1D\nCoordinates: [\"iron_core.segment[:].b_field\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: iron_core.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"langmuir_probes.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].b_field_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].b_field_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].distance_separatrix_midplane.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].fluence.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].heat_flux_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].ion_saturation_current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].j_i_parallel_sigma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].multi_temperature_fits[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].multi_temperature_fits[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].multi_temperature_fits[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].n_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area\nArea of the probe surface exposed to the plasma (use when assuming constant effective collection area)Units: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.data\nDataUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].surface_area_effective.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_floating_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.embedded[:].v_plasma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.embedded[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.name\nIDS nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.equilibrium_id.occurrence\nIDS occurrenceData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].b_field_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].heat_flux_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].ion_saturation_current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_kurtosis.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_saturation.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.data\nDataUnits: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].j_i_skew.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity\nIndicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.validity_timed\nIndicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].collector[:].v_floating_sigma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_separatrix_midplane.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].distance_x_point_z.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.data\nDataData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].mach_number_parallel.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].n_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.validity\nIndicator of the validity of the position data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.validity_timed\nIndicator of the validity of the position data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].position_average.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_e_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].t_i_average.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].time\nTime of maximum penetration of the probe during a given plungeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\nTime vector for describing the dynamics within the plungeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity\nIndicator of the validity of the data for the whole plunge. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].plunge[:].v_plasma.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].time_within_plunge\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.reciprocating[:].surface_area\nArea of the surface exposed to the plasma of each collector (constant assuming negligible dependence on e.g. the magnetic field line angle)Units: m^2\nData Type: FLT_1D\nCoordinates: [\"langmuir_probes.reciprocating[:].plunge[:].collector\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: langmuir_probes.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].distance_to_antenna\nRadial distance to the antenna mouth (grid for the electron density profile). 0 at antenna mouth, increasing towards the plasmaUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.conversion\nConversion efficiency of electric power to microwave powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.coupling\nCoupling efficiency of launched microwave power to the plasmaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].efficiency.transmission\nTransmission efficiency of microwave power from generator to antennaData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].frequency\nFrequencyUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].identifier\nIdentifier of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].model_name\nName of the antenna model used for antenna spectrum computationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].identifier\nIdentifier of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].name\nName of the moduleData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].phase.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].reflection_coefficient.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].module[:].reflection_coefficient.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].module[:].reflection_coefficient.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"lh_antennas.antenna[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_parallel_peak.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].n_parallel_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].n_parallel_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].name\nName of the antenna (unique within the set of all antennas of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].phase_average.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].phase_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].phase_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.definition\nDefinition of the reference pointData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.phi.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.phi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.phi.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.r.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.z.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].position.z.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].position.z.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_forward.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_forward.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_forward.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_reflected.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].power_reflected.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].power_reflected.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].pressure_tank.data\nDataUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].pressure_tank.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].pressure_tank.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].reflection_coefficient.data\nDataData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].reflection_coefficient.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].reflection_coefficient.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].n_pol\nRefraction index in the poloidal direction. The poloidal angle is defined from the reference point; the angle at a point (R,Z) is given by atan((Z-Zref)/(R-Rref)), where Rref=referencepoint/r and Zref=referencepoint/zData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].n_tor\nRefraction index in the toroidal directionData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].name\nName of the rowData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.antenna[:].row[:].position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].power_density_spectrum_1d\n1D power density spectrum dP/dn_tor, as a function of timeUnits: W\nData Type: FLT_2D\nCoordinates: [\"lh_antennas.antenna[:].row[:].n_tor\", \"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].power_density_spectrum_2d\n2D power density spectrum d2P/(dntor.dnpol), as a function of timeUnits: W\nData Type: FLT_3D\nCoordinates: [\"lh_antennas.antenna[:].row[:].n_tor\", \"lh_antennas.antenna[:].row[:].n_pol\", \"lh_antennas.antenna[:].row[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.antenna[:].row[:].time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"lh_antennas.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"lh_antennas.power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.reference_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.reference_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: lh_antennas.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].area\nArea of each turn of the sensor; becomes effective area when multiplied by the turnsUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].bandwidth_3db\n3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].field.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].indices_differential\nIndices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].length\nLength of the sensor along it's normal vector (n)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear\nArray of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linearUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].non_linear_response.b_field_non_linear\nMagnetic field value taking into account the non-linear response of the probeUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].non_linear_response.b_field_linear\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].poloidal_angle\nAngle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].toroidal_angle\nAngle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].turns\nTurns in the coil, including signData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_pol_probe[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_pol_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].area\nArea of each turn of the sensor; becomes effective area when multiplied by the turnsUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].bandwidth_3db\n3dB bandwith (first index : lower frequency bound, second index : upper frequency bound)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].field.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].field.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].identifier\nID of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].indices_differential\nIndices (from the bpol_probe array of structure) of the two probes used to build the field difference field(second index) - field(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].length\nLength of the sensor along it's normal vector (n)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].name\nName of the probeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear\nArray of magnetic field values (corresponding to the assumption of a linear relation between magnetic field and probe coil current), for each of which the probe non-linear response is given in ../bfieldnon_linearUnits: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].non_linear_response.b_field_non_linear\nMagnetic field value taking into account the non-linear response of the probeUnits: T\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].non_linear_response.b_field_linear\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].poloidal_angle\nAngle of the sensor normal vector (vector parallel to the the axis of the coil, n on the diagram) with respect to horizontal plane (clockwise theta-like angle). Zero if sensor normal vector fully in the horizontal plane and oriented towards increasing major radius. Values in [0 , 2Pi]Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].toroidal_angle\nAngle of the projection of the sensor normal vector (n) in the horizontal plane with the increasing R direction (i.e. grad(R)) (angle is counter-clockwise from above as in cocos=11 phi-like angle). Values should be taken modulo pi with values within (-pi/2,pi/2]. Zero if projected sensor normal is parallel to grad(R), pi/2 if it is parallel to grad(phi).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].turns\nTurns in the coil, including signData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.b_field_tor_probe[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.b_field_tor_probe[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"magnetics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].data\nDataUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"magnetics.diamagnetic_flux[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].method_name\nName of the calculation methodData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.diamagnetic_flux[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].area\nEffective area (ratio between flux and average magnetic field over the loop)Units: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.data\nDataUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"magnetics.flux_loop[:].flux.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].flux.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.flux_loop[:].flux.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].gm9\nIntegral of 1/R over the loop area (ratio between flux and magnetic rigidity R0.B0). Use only if ../type/index = 3 to 6, leave empty otherwise.Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].identifier\nID of the flux loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].indices_differential\nIndices (from the flux_loop array of structure) of the two flux loops used to build the flux difference flux(second index) - flux(first index). Use only if ../type/index = 6, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].name\nName of the flux loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].position[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.flux_loop[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.flux_loop[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.flux_loop[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"magnetics.ip[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].method_name\nName of the calculation methodData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.ip[:].time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].area\nEffective area of the loop wrapped around the guiding centre. In case of multiple layers, sum of the areas of each layerUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"magnetics.rogowski_coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].current.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.rogowski_coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].identifier\nID of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].indices_compound\nIndices (from the rogowskicoil array of structure) of the partial Rogoswkis used to build the coumpound signal (sum of the partial Rogoswki signals). Can be set to any unique integer value for each section of a compound rogowski coil. Use only if ../measurequantity/index = 5, leave empty otherwiseData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].measured_quantity.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].position[:].z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.rogowski_coil[:].turns_per_metre\nNumber of turns per unit length. In case of multiple layers, turns are counted for a single layerUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].divertor_index\nIf the shunt is located on a given divertor, index of that divertor in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].identifier\nAlphanumeric identifier of the shuntData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].name\nName of the shuntData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].position.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].resistance\nShunt resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].target_index\nIf the shunt is located on a divertor target, index of that target in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].tile_index\nIf the shunt is located on a divertor tile, index of that tile in the divertors IDSData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"magnetics.shunt[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.shunt[:].voltage.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"magnetics.shunt[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: magnetics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mhd.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].a_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].a_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].electrons.temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].electrons.temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_r[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_tor_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_tor_r[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].j_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].j_z[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].mass_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].mass_density[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].n_i_total[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].n_i_total[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: eV\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].t_i_average[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].t_i_average[:].values\nOne scalar value is provided per element in the grid subset.Units: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1.T^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_parallel_over_b_field[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_parallel_over_b_field[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1.T^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_r[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].velocity_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].velocity_z[:].values\nOne scalar value is provided per element in the grid subset.Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].vorticity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity[:].values\nOne scalar value is provided per element in the grid subset.Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].vorticity_over_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].vorticity_over_r[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"mhd.ggd[:].zeff[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ggd[:].zeff[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"mhd.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mhd_linear.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.equations.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.fluids_n\nNumber of fluids considered in the modelData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ideal_flag\n1 if ideal MHD is used to populate this IDS, 0 for non-ideal MHDData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.model_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].amplitude_multiplier\nMultiplier that is needed to convert the linear mode structures to the amplitude of a non-linearly saturated mode in physical units. If empty, it means that the structures contains no information about non-linearly saturated modeUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].ballooning_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].energy_perturbed\nPerturbed energy associated to the modeUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].growthrate\nLinear growthrate of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].m_pol_dominant\nDominant poloidal mode number defining the mode rational surface; for TAEs the lower of the two main m's has to be specifiedData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].n_tor\nToroidal mode number of the MHD modeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].perturbation_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].phase\nAdditional phase offset of modeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate1.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate2.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.a_field_perturbed.coordinate3.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].imaginary\nImaginary part of the frequency, for a given radial position and every root found at this positionUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.alfven_frequency_spectrum[:].real\nReal part of the frequency, for a given radial position and every root found at this positionUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate1.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate2.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.b_field_perturbed.coordinate3.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.imaginary\nImaginary partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_parallel.real\nReal partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.imaginary\nImaginary partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.displacement_perpendicular.real\nReal partUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: kg.m^-3\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: kg.m^-3\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.imaginary\nImaginary partUnits: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.mass_density_perturbed.real\nReal partUnits: kg.m^-3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.ntv.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.imaginary\nImaginary partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.phi_potential_perturbed.real\nReal partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: Pa\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: Pa\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.imaginary\nImaginary partUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.pressure_perturbed.real\nReal partUnits: Pa\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: V\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.imaginary\nImaginary partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.psi_potential_perturbed.real\nReal partUnits: V\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_maxwell.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.imaginary\nImaginary part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.stress_reynolds.real\nReal part of the stress tensor, for various radial positionsUnits: N.m^-2\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_alfven\nAlven time=R/vA=R0 sqrt(mi ni(rho))/B0Units: s\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.tau_resistive\nResistive time = mu0 rho*rho/1.22/etaneoUnits: s\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: eV\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: eV\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.imaginary\nImaginary partUnits: eV\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.temperature_perturbed.real\nReal partUnits: eV\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate1.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate2.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: m/s\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.imaginary\nImaginary partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].plasma.velocity_perturbed.coordinate3.real\nReal partUnits: m/s\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].plasma.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].radial_mode_number\nRadial mode numberData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate1.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate2.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T.m\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.a_field_perturbed.coordinate3.real\nReal partUnits: T.m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate1.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate2.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_imaginary\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (imaginary part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.coefficients_real\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity (real part) with finite elements, provided on the 2D gridUnits: T\nData Type: FLT_3D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.imaginary\nImaginary partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.b_field_perturbed.coordinate3.real\nReal partUnits: T\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.jacobian\nAbsolute value of the jacobian of the coordinate systemUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.r\nValues of the major radius on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_contravariant\nContravariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.tensor_covariant\nCovariant metric tensor on every point of the grid described by grid_typeUnits: mixed\nData Type: FLT_4D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\", \"1...3\", \"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.z\nValues of the Height on the gridUnits: m\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.coordinate_system.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim1\", \"mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.time_slice[:].toroidal_mode[:].vacuum.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"mhd_linear.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mhd_linear.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].geometric_coefficients\nSet of 9 geometric coefficients providing the MSE polarisation angle as a function of the local electric and magnetic field components (these are related to the angle between beam and line of sight). The list is ordered as follows : coefficients of BZ, BR, Bphi, ER (numerator of the MSE angle expression); coefficients of BZ, BR, Bphi, ER, EZ (denominator)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...9\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].active_spatial_resolution[:].width.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"mse.channel[:].polarisation_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.channel[:].polarisation_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"mse.channel[:].polarisation_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"mse.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: mse.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].available_launch_power\nAvailable launch powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_current_fraction.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"nbi.unit[:].beam_current_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_current_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_power_fraction.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"nbi.unit[:].beam_power_fraction.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beam_power_fraction.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].angle\nAngle of inclination between a beamlet at the centre of the injection unit surface and the horiontal planeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.angles\nAngle of inclination between a line at the centre of a beamlet and the horizontal plane, for each beamletUnits: rad\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.power_fractions\nFraction of power of a unit injected by each beamletData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].beamlets.tangency_radii\nTangency radius (major radius where the central line of a beamlet is tangent to a circle around the torus), for each beamletUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].beamlets_group[:].beamlets.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].direction\nDirection of the beam seen from above the torus: -1 = clockwise; 1 = counter clockwiseData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].horizontal\nThe horiztonal beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].particles_fraction\nFraction of injected particles in the componentData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].divergence_component[:].vertical\nThe vertical beamlet divergence of the component. Here the divergence is defined for Gaussian beams as the angel where the beam density is reduced by a factor 1/e compared to the maximum density. For non-Gaussian beams the divergence is sqrt(2)mean((x-mean(x))**2), where x is the angle and the mean should be performed over the beam density, P(x): mean(y)=int(yP(x)*dx).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.focal_length_horizontal\nHorizontal focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum horizontal widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.focal_length_vertical\nVertical focal length along the beam line, i.e. the point along the centre of the beamlet-group where the beamlet-group has its minimum vertical widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.width_min_horizontal\nThe horizontal width (Full Width at Half Maximum) of the beamlets group at the horizontal focal pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].focus.width_min_vertical\nThe vertical width (Full Width at Half Maximum) of the beamlets group at the vertical focal pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tangency_radius\nTangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_angle\nVariation of the angle of inclination between a beamlet at the centre of the injection unit surface and the horiontal planeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].delta_tangency_radius\nVariation of the tangency radius (major radius where the central line of a NBI unit is tangent to a circle around the torus)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].tilting[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].width_horizontal\nHorizontal width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid) Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].beamlets_group[:].width_vertical\nVertical width (dimensions of the smallest rectangle that surrounds the outer dimensions of the beamlets) of the beamlet group at the injection unit surface (or grounded grid)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].efficiency.conversion\nConversion efficiency of electric power to neutral beam powerData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].efficiency.transmission\nTransmission efficiency of neutral beam from source to portData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].energy.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].energy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].energy.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].identifier\nID of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].name\nName of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].power_launched.data\nDataUnits: W\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].power_launched.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].power_launched.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"nbi.unit[:].source.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].source.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: nbi.unit[:].species.z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.bias\nADC signal biasUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.discriminator_level_lower\nLower level discriminator of ADCData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.discriminator_level_upper\nUpper level discriminator of ADCData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.impedance\nADC impedanceUnits: ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.input_range\nADC input rangeUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].adc.sampling_rate\nNumber of samples recorded per secondData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].b_field_sensor.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].b_field_sensor.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].b_field_sensor.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.x\nComponents along X axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.y\nComponent along Y axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.direction_to_detector.z\nComponent along Z axis for each voxelUnits: m\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.emission_grid.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].field_of_view.solid_angle\nAverage solid angle that the detector covers within the voxelUnits: sr\nData Type: FLT_3D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values\nArray of values for the eventUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values\nArray of values for the eventUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.neutron_flux\nGrouped neutron flux in the detector from one neutron energy bin emitted by the current plasma voxel towards the detectorUnits: m^-2.neutron^-1\nData Type: FLT_5D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\", \"neutron_diagnostic.detector[:].green_functions.source_neutron_energies\", \"neutron_diagnostic.detector[:].green_functions.event_in_detector_neutron_flux.values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.neutron_flux_integrated_flags\nArray of flags telling, for each coordinate of the neutronflux, whether the neutronflux has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1Data Type: INT_1D\nCoordinates: [\"1...5\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.response_function\nNumber of events occurring in the detector from one neutron energy bin emitted by the current plasma voxel towards the detectorUnits: events.neutron^-1\nData Type: FLT_5D\nCoordinates: [\"neutron_diagnostic.detector[:].field_of_view.emission_grid.r\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.z\", \"neutron_diagnostic.detector[:].field_of_view.emission_grid.phi\", \"neutron_diagnostic.detector[:].green_functions.source_neutron_energies\", \"neutron_diagnostic.detector[:].green_functions.event_in_detector_response_function.values\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.response_function_integrated_flags\nArray of flags telling, for each coordinate of the responsefunction, whether the responsefunction has been integrated over this coordinate (1) or not (0). If it has been integrated over a coordinate, the size related to this coordinate must be equal to 1Data Type: INT_1D\nCoordinates: [\"1...5\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].green_functions.source_neutron_energies\nArray of source neutron energy binsUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].count_limit_max\nMaximum count limit under which the detector response is linearUnits: counts.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].count_limit_min\nMinimum count limit above which the detector response is linearUnits: counts.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].counting.data\nDataUnits: counts.s^-1\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].mode[:].counting.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].counting.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].spectrum.data\nDataUnits: counts.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"neutron_diagnostic.detector[:].mode[:].spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].mode[:].spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].name\nName of the detectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].nuclei_n\nNumber of target nuclei in the dectectorData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_high_voltage.voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_out.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].supply_low_voltage.voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature\nTemperature of the detectorUnits: K\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].temperature_sensor.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].temperature_sensor.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].temperature_sensor.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.amplitude.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].test_generator.amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.fall_time\nPeak fall timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.frequency.data\nDataUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.detector[:].test_generator.frequency.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.frequency.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.power_switch\nPower switch (1=on, 0=off)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.rise_time\nPeak rise timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.detector[:].test_generator.shape.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.fusion_power\nFusion power reconstructed from the detectors signalsUnits: W\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.neutron_flux_total\nTotal Neutron Flux reconstructed from the detectors signalsUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"neutron_diagnostic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutron_diagnostic.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.first_wall.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.first_wall.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.flux_r\nAverage radial component of the neutron fluxUnits: W/m^2\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.flux_z\nAverage vertical component of the neutron fluxUnits: W/m^2\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: neutronics.time_slice[:].wall_loading.power\nLocal neutron power (ie. integrated neutron flux)Units: W\nData Type: FLT_1D\nCoordinates: [\"neutronics.first_wall.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"ntms.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].calculation_method\nDescription of how the mode evolution is calculatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].delta_diff\nExtra diffusion coefficient for the transport equations of Te, ne, Ti Units: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].deltaw[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].deltaw[:].value\nValue of the contributionUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.calculation_method\nDescription of how the mode evolution is calculatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.delta_diff\nExtra diffusion coefficient for the transport equations of Te, ne, Ti Units: m^2.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.deltaw[:].value\nValue of the contributionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dfrequency_dt\nTime derivative of the frequency of the modeUnits: s^-2\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dphase_dt\nTime derivative of the phase of the modeUnits: rad/s\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.dwidth_dt\nTime derivative of the full width of the modeUnits: m/s\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.phase\nPhase of the modeUnits: rad\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.rho_tor\nFlux coordinate on which the mode is centredUnits: m\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.rho_tor_norm\nNormalised flux coordinate on which the mode is centredData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\nTime array used to describe the detailed evolution of the NTMUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.torque[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.torque[:].value\nValue of the contributionUnits: kg.m^2.s^-2\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].detailed_evolution.width\nFull width of the modeUnits: m\nData Type: FLT_1D\nCoordinates: [\"ntms.time_slice[:].mode[:].detailed_evolution.time_detailed\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dfrequency_dt\nTime derivative of the frequency of the modeUnits: s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dphase_dt\nTime derivative of the phase of the modeUnits: rad/s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].dwidth_dt\nTime derivative of the full width of the modeUnits: m/s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].frequency\nFrequency of the modeUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.cause\nCause of the mode onsetData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.m_pol\nPoloidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.n_tor\nToroidal mode numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.phase\nPhase of the mode at onsetUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.time_offset\nOffset time (when a mode disappears). If the mode reappears later in the simulation, use another index of the mode array of structureUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.time_onset\nOnset timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].onset.width\nSeed island full width at onset timeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].phase\nPhase of the modeUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].rho_tor\nFlux coordinate on which the mode is centredUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].rho_tor_norm\nNormalised flux coordinate on which the mode is centredData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].torque[:].name\nName of the contributionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].torque[:].value\nValue of the contributionUnits: kg.m^2.s^-2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].mode[:].width\nFull width of the modeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"ntms.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: ntms.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"operational_instrumentation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].acceleration.data\nDataUnits: m.s^-2\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].acceleration.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].acceleration.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_points[:].z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].attachement_uris\nIMAS URI of the system(s) to which this sensor is attached. Two for displacement sensors, one for the other types of sensorsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].direction_second.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].gauge_length\nLength of the strain gaugeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].identifier\nID of the sensorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].length.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].length.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].length.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].name\nName of the sensorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain.data\nDataData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].strain.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain_rosette.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"operational_instrumentation.sensor[:].strain_rosette.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].strain_rosette.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].temperature.data\nDataUnits: K\nData Type: FLT_1D\nCoordinates: [\"operational_instrumentation.sensor[:].temperature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].temperature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.sensor[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: operational_instrumentation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pellets.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].name\nName of the launcher (unique within the set of all launchers of the experiment)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.size\nSize of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the lengthData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].shape.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.launcher[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].frequency\nFrequency of pellets launchedUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].density\nMaterial density of the species in the pelletUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].fraction\nAtomic fraction of the species in the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].sublimation_energy\nSublimation energy per atomUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].layer[:].thickness\nLayer thicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_geometry.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.ablated_particles\nNumber of ablated particles (electrons) along the pellet path Data Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.ablation_rate\nAblation rate (electrons) along the pellet path Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.distance\nDistance along the pellet path, with the origin taken at pathgeometry/firstpoint. Used as the main coordinate for the path_profiles structure Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.n_e\nElectron density along the pellet path Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.position.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.position.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.psi\nPoloidal flux along the pellet path Units: Wb\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm\nNormalised toroidal coordinate along the pellet path Data Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.rho_tor_norm_drift\nDifference to due ExB drifts between the ablation and the final deposition locations, in terms of the normalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.t_e\nElectron temperature along the pellet path Units: eV\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].path_profiles.velocity\nPellet velocity along the pellet path Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"pellets.time_slice[:].pellet[:].path_profiles.distance\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.label\nString identifying the neutral molecule (e.g. H2, D2, T2, N2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].propellant_gas.molecules_n\nNumber of molecules of the propellant gas injected in the vacuum vessel when launching the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.size\nSize of the pellet in the various dimensions, depending on the shape type. Spherical pellets: size(1) is the radius of the pellet. Cylindrical pellets: size(1) is the radius and size(2) is the height of the cylinder. Rectangular pellets: size(1) is the height, size(2) is the width and size(3) is the lengthUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].shape.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].density\nMaterial density of the species in the pelletUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].fraction\nAtomic fraction of the species in the pelletData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].sublimation_energy\nSublimation energy per atomUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].pellet[:].velocity_initial\nInitial velocity of the pellet as it enters the vaccum chamberUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pellets.time_slice[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].connections\nDescription of the supplies and coils connections (nodes) across the circuit. Nodes of the circuit are listed as the first dimension of the matrix. Supplies (listed first) and coils (listed second) SIDES are listed as the second dimension. Thus the second dimension has a size equal to 2*(Nsupplies+Ncoils). Nsupplies (resp. Ncoils) is the total number of supplies (resp. coils) listed in the supply (resp.coil) array of structure, i.e. including also supplies/coils that are not part of the actual circuit. The (i,j) matrix elements are 1 if the j-th supply or coil side is connected to the i-th node, or 0 otherwise. For coils, sides are listed so that a current flowing from side 1 to side 2 (inside the coil) is positive (i.e. counter-clockwise when seen from above).Data Type: INT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.circuit[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].identifier\nID of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].name\nName of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].type\nType of the circuitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.circuit[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.circuit[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max\nList of values of the maximum magnetic field on the conductor surface (coordinate for currentlimitmax)Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max_timed.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].b_field_max_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].b_field_max_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].current_limit_max\nMaximum tolerable current in the conductorUnits: A\nData Type: FLT_2D\nCoordinates: [\"pf_active.coil[:].b_field_max\", \"pf_active.coil[:].temperature\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].area\nCross-sectional areas of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].identifier\nIdentifier of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].name\nName of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].element[:].turns_with_sign\nNumber of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].energy_limit_max\nMaximum Energy to be dissipated in the coilUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_radial.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial_crushing.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_radial_crushing.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_radial_crushing.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_vertical.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical_crushing.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].force_vertical_crushing.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].force_vertical_crushing.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].function[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].identifier\nAlphanumeric identifier of coils used for convenienceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance_additional.data\nDataUnits: Ohm\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].resistance_additional.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].resistance_additional.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].temperature\nList of values of the conductor temperature (coordinate for currentlimitmax)Units: K\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.coil[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.combination_matrix\nForce limits are expressed as a linear combination of the forces on each individual coil. The weights of the linear combination are given by this matrix, while the limits are given by the sibling nodes limitmin and limitmax. Each row of this matrix corresponds to a force limit. The columns represent, for each coil, the 4 types of forces on the coil namely [coil1radial, coil1vertical, coil1radialcrush, coil1verticalcrush, coil2radial, coil2vertical, coil2radialcrush, coil2verticalcrush, ...]. There are therefore 4*coils_n columns.Data Type: FLT_2D\nCoordinates: [\"pf_active.force_limits.limit_max\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.force.data\nDataUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.force_limits.force.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.force.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.limit_max\nMaximum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unboundedUnits: N\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.force_limits.limit_min\nMinimum force limit, for each limit (line of the combination matrix). EMPTY_FLT value means unboundedUnits: N\nData Type: FLT_1D\nCoordinates: [\"pf_active.force_limits.limit_max\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_active.supply[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limit_max\nMaximum current in the supplyUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limit_min\nMinimum current in the supplyUnits: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].current_limiter_gain\nGain to prevent overcurrent in a linear model of the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].delay\nPure delay in the supplyUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].energy_limit_max\nMaximum energy to be dissipated in the supply during a pulseUnits: J\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].filter_denominator\nCoefficients of the denominator, in increasing order : b0 + b1s + ... + bms^m; used for a linear supply descriptionUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].filter_numerator\nCoefficients of the numerator, in increasing order : a0 + a1s + ... + ans^n; used for a linear supply descriptionUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].identifier\nIdentifier of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].name\nName of the PF supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].nonlinear_model\nDescription of the nonlinear transfer function of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].resistance\nPower supply internal resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].type\nType of the supply; TBD add free description of non-linear power suppliesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"pf_active.supply[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage_limit_max\nMaximum voltage from the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.supply[:].voltage_limit_min\nMinimum voltage from the supplyUnits: V\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_active.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_passive.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].current\nPassive loop currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].area\nCross-sectional areas of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_passive.loop[:].element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].identifier\nIdentifier of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].name\nName of this elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].element[:].turns_with_sign\nNumber of effective turns in the element for calculating magnetic fields of the coil/loop; includes the sign of the number of turns (positive means current is counter-clockwise when seen from above)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].name\nName of the loopData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].resistance\nPassive loop resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].resistivity\nPassive loop resistivityUnits: Ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.loop[:].time\nTimebase for the dynamic nodes of this loop located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_passive.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pf_plasma.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].area\nCross-sectional area of the elementUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].current\nCurrent in the plasma elementUnits: A\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.r\nCentre major radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.radius_inner\nInner radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.radius_outer\nOuter radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.annulus.z\nCentre heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.curvature_radii\nCurvature radius of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.r\nMajor radii of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.arcs_of_circle.z\nHeight of the start point of each arc of circleUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.arcs_of_circle.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.geometry_type\nType used to describe the element shape (1:'outline', 2:'rectangle', 3:'oblique', 4:'arcs of circle, 5: 'annulus', 6 : 'thick line') Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.alpha\nInclination of first angle measured counter-clockwise from horizontal outwardly directed radial vector (grad R).Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.beta\nInclination of second angle measured counter-clockwise from vertically upwards directed vector (grad Z). If both alpha and beta are zero (rectangle) then the simpler rectangular elements description should be used.Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.length_alpha\nLength of the parallelogram side inclined with angle alpha with respect to the major radius axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.length_beta\nLength of the parallelogram side inclined with angle beta with respect to the height axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.r\nMajor radius of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.oblique.z\nHeight of the reference point (from which the alpha and beta angles are defined, marked by a + on the diagram)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"pf_plasma.element[:].geometry.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.height\nVertical full heightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.r\nGeometric centre RUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.width\nHorizontal full widthUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.rectangle.z\nGeometric centre ZUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].geometry.thick_line.thickness\nThicknessUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.element[:].time\nTimebase for the dynamic nodes located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pf_plasma.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].e_field_parallel\nParallel electric field along each field lineUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].e_field_townsend\nTownsend electric field along each field lineUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.b_field_lines[:].grid.dim1\", \"plasma_initiation.b_field_lines[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].lengths\nLength of each field lineUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].open_fraction\nFraction of open field lines : ratio open fields lines / (open+closed field lines)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].pressure\nPrefill gas pressure used in Townsend E field calculationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].starting_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].starting_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].starting_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].townsend_or_closed_grid_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.b_field_lines[:].townsend_or_closed_positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.b_field_lines[:].townsend_or_closed_positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"plasma_initiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_perpendicular.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.b_field_perpendicular.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_perpendicular.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_stray.data\nDataUnits: T\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.b_field_stray.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.b_field_stray.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.connection_length.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.connection_length.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.connection_length.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.coulomb_logarithm.data\nDataData Type: FLT_1D\nCoordinates: [\"plasma_initiation.global_quantities.coulomb_logarithm.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.global_quantities.coulomb_logarithm.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].e_field_tor\nToroidal component of the electric fieldUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.profiles_2d[:].grid.dim1\", \"plasma_initiation.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid.volume_element\nElementary plasma volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]Units: m^3\nData Type: FLT_2D\nCoordinates: [\"plasma_initiation.profiles_2d[:].grid.dim1\", \"plasma_initiation.profiles_2d[:].grid.dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: plasma_initiation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.data\nDataData Type: FLT_1D\nCoordinates: [\"polarimeter.channel[:].ellipticity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"polarimeter.channel[:].ellipticity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].ellipticity_initial\nInitial ellipticity before entering the plasmaUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.data\nDataUnits: rad\nData Type: FLT_1D\nCoordinates: [\"polarimeter.channel[:].faraday_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].faraday_angle.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"polarimeter.channel[:].faraday_angle.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].polarisation_initial\nInitial polarisation vector before entering the plasmaUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.channel[:].wavelength\nWavelength used for polarimetryUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"polarimeter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: polarimeter.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"pulse_schedule.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].n_i_volume_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.ion[:].z_ion\nIon chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_greenwald_fraction.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_lcfs.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_pedestal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_pedestal_greenwald_fraction.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_profile_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_e_volume_average.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_h_over_n_d.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.n_t_over_n_d.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].flow_rate.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].identifier\nIdentifier of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].name\nName of the valveData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.valve[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_line_of_sight.third_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.density_control.zeff_pedestal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.density_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].identifier\nIdentifier of the beamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].name\nName of the beamData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].power_launched.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_pol.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.beam[:].steering_angle_tor.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ec.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.power_launched.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ec.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_state.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].acquisition_strategy.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].duration\nDuration of this eventUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].identifier\nUnique identifier of this event provided by the scheduling / event handlerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].listeners\nSystems listening to this eventData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].provider\nSystem having generated this eventData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].time_stamp\nTime stamp of this eventUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.event[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.beta_normal.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.i_plasma.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.li_3.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.loop_voltage.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.flux_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.flux_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].identifier\nIdentifier of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].name\nName of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].phase.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.antenna[:].power_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.ic.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ic.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].frequency.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].identifier\nIdentifier of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].n_parallel.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].name\nName of the antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].phase.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.antenna[:].power_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.lh.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.lh.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].energy.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].identifier\nIdentifier of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].name\nName of the NBI unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.nbi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].power.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].fraction\nRelative fraction of this species (in molecules) in the gas mixtureData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.nbi.unit[:].species[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].deposition_rho_tor_norm_width.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.launcher[:].frequency.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pellet.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pellet.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].current.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].identifier\nIdentifier of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].resistance_additional.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.coil[:].voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].current.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].identifier\nIdentifier of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].name\nName of the supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower and upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.pf_active.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.supply[:].voltage.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.pf_active.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.active_limiter_point.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.boundary_outline[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.current_centroid.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_lower.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.elongation_upper.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].angle\nAngle between the direction in which the gap is measured (in the poloidal cross-section) and the horizontal axis. Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].identifier\nIdentifier of the gapData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].name\nName of the gapData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].r\nMajor radius of the reference pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].value.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.gap[:].z\nHeight of the reference pointUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.geometric_axis.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.magnetic_axis.z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.minor_radius.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.ovality.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_lower_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.squareness_upper_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.strike_point[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.tilt.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_inner.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_lower.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_minor.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_outer.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.triangularity_upper.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.twist.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.x_point[:].z.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_max.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.position_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.position_control.z_r_min.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.dpressure_dpsi.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: Pa.Wb^-1\nData Type: FLT_2D\nCoordinates: [\"pulse_schedule.profiles_control.psi_norm\", \"pulse_schedule.profiles_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.f_df_dpsi.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"pulse_schedule.profiles_control.psi_norm\", \"pulse_schedule.profiles_control.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.psi_norm\nRadial dimensionData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.profiles_control.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum.reference\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.envelope_type\nEnvelope type: 0:relative: means that the envelope upper and lower bound values are defined respectively as reference.data * reference.dataerrorupper and reference.data * reference.dataerrorlower. 1: absolute: the envelope upper and lower bound values are given respectively by reference/dataerrorupper and reference/dataerrorlower. Lower are upper are taken in the strict mathematical sense, without considering absolute values of the dataData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference\nReference waveform. Caution : error bars of the reference/data node are not used in the usual sense, instead they are used to describe the control envelope, with a meaning depending on the chosen envelope_type option.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference_name\nReference name (e.g. in the native pulse schedule system of the device)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.b_field_tor_vacuum_r.reference_type\nReference type: 0:relative (don't use for the moment, to be defined later when segments are introduced in the IDS structure); 1: absolute: the reference time trace is provided in the reference/data nodeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.mode\nControl mode (operation mode and/or settings used by the controller)Data Type: INT_1D\nCoordinates: [\"pulse_schedule.tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.tf.time\nTimebase for the dynamic nodes located at this level of the IDS structure and belowUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: pulse_schedule.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"radiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"radiation.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].electrons.emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].electrons.emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].ion[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].neutral[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].emissivity[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power\nTotal power emitted by all speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_electrons\nPower emitted by electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_ion_total\nTotal power emitted by all ion speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_lcfs.power_neutral_total\nTotal power emitted by all neutral speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power\nTotal power emitted by all speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_electrons\nPower emitted by electronsUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_ion_total\nTotal power emitted by all ion speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].inside_vessel.power_neutral_total\nTotal power emitted by all neutral speciesUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].electrons.emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].electrons.power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].emissivity_ion_total\nEmissivity (summed over ion species)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].emissivity_neutral_total\nEmissivity (summed over neutral species)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].label\nString identifying the neutral species (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].emissivity\nEmissivity from this speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].power_inside\nRadiated power from inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].power_inside_ion_total\nTotal power from ion species (summed over ion species) inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].power_inside_neutral_total\nTotal power from ion species (summed over neutral species) inside the flux surface (volume integral of the emissivity inside the flux surface)Units: W\nData Type: FLT_1D\nCoordinates: [\"radiation.process[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.process[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"radiation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: radiation.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"real_time_data.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].name\nTopic nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].sample\nIndex of sample (time stamp counter)Data Type: INT_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].allocated_position\nAllocation of signal to a position in the SDN (1..N), or several positions in case of signal reshaping; this will be implementation specificData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].data_str\nSignal data (e.g. diagnostic signal or PCS command), serialized as a stringData Type: STR_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].data_type\nSignal data typeData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].name\nSignal nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].signal[:].quality\nIndicator of the quality of the signal. Following ITER PCS documentation (https://user.iter.org/?uid=354SJ3&action=get_document), possible values are: 1 - GOOD (the nominal state); 2 - INVALID (data no usable); 3 - DATA INTEGRITY ERROR (e.g. out of bounds with respect to expectations, calibration error,...)Data Type: INT_1D\nCoordinates: [\"real_time_data.topic[:].time_stamp\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: real_time_data.topic[:].time_stamp\nTime of creation for all signals belonging to this topic. A set of time stamps can be recorded if neededUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].amplitude.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].antenna_detection_static.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_detection_static.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].antenna_emission_static.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antenna_emission_static.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_detection.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].antenna_emission.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_detection.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].antennas_orientation[:].line_of_sight_emission.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.e_field_radial\nRadial electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.radial_width\nWidth in the radial direction over which fluctuating profiles are processedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.shift\nDoppler frequency shift (for the main peak of the power spectrum)Units: Hz\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.time_width\nWidth of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].doppler.wavenumber\nWavenumber probed by the diagnosticUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.channel[:].doppler.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.dn_e_over_n_e\nRelative amplitude of the density fluctuations post-processed for swept and fixed frequency (profile/one point)Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_level.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.radial_width\nWidth in the radial direction over which fluctuating profiles are processedUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_level.time_width\nWidth of the time interval over which fluctuating profiles are processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier\nArray of frequencies used for the Fourier transformUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.power_log\nPower spectrum in log scaleUnits: dB\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].fluctuations_spectrum.frequencies_fourier\", \"reflectometer_fluctuation.channel[:].fluctuations_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].fluctuations_spectrum.time_width\nWidth of the time interval over which the spectrum is processed. By convention, the time interval starts at time-time_width and ends at time.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].frequencies.data\nDataUnits: Hz\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].frequencies.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].frequencies.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].phase.data\nDataUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.i_component\nI component of the IQ detector used to retrieve the phase of signal's envelopeUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].raw_signal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.q_component\nQ component of the IQ detector used to retrieve the phase of signal's envelopeUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_fluctuation.channel[:].raw_signal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].raw_signal.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.channel[:].sweep_time\nDuration of a sweepUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"reflectometer_fluctuation.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_fluctuation.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_fluctuation.type\nType of reflectometer (frequency_swept, radar, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].amplitude.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].amplitude.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].amplitude.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.channel[:].antenna_detection.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_detection.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.channel[:].antenna_emission.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].antenna_emission.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].cut_off_frequency\nCut-off frequency as a function of measurement position and timeUnits: Hz\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].frequencies\nArray of frequencies scanned during a sweepUnits: Hz\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_detection.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].line_of_sight_emission.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].phase.data\nDataUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].phase.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].phase.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.channel[:].sweep_time\nDuration of a sweepUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"reflectometer_profile.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.n_e.data\nDataUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.psi\nPoloidal fluxUnits: W\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.rho_tor_norm\nNormalised toroidal flux coordinateData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.theta\nPoloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"reflectometer_profile.n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundaryUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axisUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"reflectometer_profile.psi_normalization.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.psi_normalization.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: reflectometer_profile.type\nType of reflectometer (frequency_swept, radar, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].frequency_main\nMain frequency used to probe the plasma (before upshifting and modulating)Units: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].i_component\nI component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vectorUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].bandwidth[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase\nPhase of the envelope of the probing signal, relative to the phase at launchUnits: rad\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase_quadrature.data\nDataUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].phase_quadrature.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].phase_quadrature.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].q_component\nQ component of the IQ detector used to retrieve the phase of signal's envelope, sampled on a high resolution time_detector grid just before each measurement time slice represented by the ../time vectorUnits: V\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].time\nTimebase for this bandwidthUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].bandwidth[:].time_detector\nHigh sampling timebase of the IQ-detector signal measurementsUnits: s\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].bandwidth[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].mode\nDetection mode \"X\" or \"O\"Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_line.data\nDataUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"refractometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_line.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.formula.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].n_e_profile_approximation.parameters\nValues of the formula's parameters alpha1, ..., alphaNUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"refractometer.channel[:].n_e_line.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"refractometer.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: refractometer.type\nType of refractometer (differential, impulse, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.Psol_R\nPsol / RUnits: W/m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.beta_normal\nNormalized total plasma beta (MHD)Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.coil_j_margin\nMagnet coil Jcrit / JmaxData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.coil_stress_margin\nMagnet coil yieldstress / maxstressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.cost\nTotal FPP costUnits: $M\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.flattop_duration\nDuration of the flattop (use Inf for steady-state)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.h98y2\nH98y2 ITER elmy H-mode confinement scaling factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.hds03\nPetty 2003 H-mode thermal energy confinement scaling factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.lh_power_threshold_fraction\nFraction of the LH power thresholdData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.ne_peaking\nOn-axis electron density / volume-averaged electron denstiyData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.power_electric_net\nNet electric power generated by the fusion power plantUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.q95\nEdge safety factorData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.q_pol_omp\nPoloidal heat flux at the outer midplaneUnits: W/m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: requirements.tritium_breeding_ratio\nTritium breeding ratio of the whole plantData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].expansion_fd3v[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].temperature\nReference temperature profile used to define the local thermal energy and the thermal velocity (for normalisation of the grid coordinates)Units: eV\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.gyro_type\nDefines how to interpret the spatial coordinates: 1 = given at the actual particle birth point; 2 =given at the gyro centre of the birth pointData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].coordinate_identifier[:].name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics\nArray of bounce harmonics kData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.expressions\nList of the expressions f(ntor,mpol,k,q,...) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.m_pol\nArray of poloidal mode numbers, where quantities vary as exp(-i.mpol.theta) and theta is the angle defined by the choice of ../../coordinateidentifier, with its centre at the magnetic axis recalled at the root of this IDSData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.n_tor\nArray of toroidal mode numbers, ntor, where quantities vary as exp(i.ntor.phi) and phi runs anticlockwise when viewed from aboveData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals.values\nValues of the orbit integralsData Type: CPX_5D\nCoordinates: [\"runaway_electrons.distribution.markers[:].orbit_integrals.expressions\", \"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].orbit_integrals.n_tor\", \"runaway_electrons.distribution.markers[:].orbit_integrals.m_pol\", \"runaway_electrons.distribution.markers[:].orbit_integrals.bounce_harmonics\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions\nList of the expressions f(eq) used in the orbit integralsData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit\nTime array along the markers last orbitUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].orbit_integrals_instant.values\nValues of the orbit integralsData Type: CPX_3D\nCoordinates: [\"runaway_electrons.distribution.markers[:].orbit_integrals_instant.expressions\", \"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].orbit_integrals_instant.time_orbit\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].positions\nPosition of the markers in the set of coordinates. The first dimension corresponds to the number of markers, the second dimension to the set of coordinatesUnits: mixed\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.distribution.markers[:].weights\", \"runaway_electrons.distribution.markers[:].coordinate_identifier\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].toroidal_mode\nIn case the orbit integrals are calculated for a given MHD perturbation, index of the toroidal mode considered. Refers to the timeslice/toroidalmode array of the MHD_LINEAR IDS in which this perturbation is describedData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.distribution.markers[:].weights\nWeight of the markers, i.e. number of real particles represented by each marker. The dimension of the vector correspond to the number of markersData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.e_field_critical_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].current_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].current_density[:].values\nOne scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_compton[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_dreicer[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_hot_tail[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_total[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].ddensity_dt_tritium[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].density[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].e_field_critical[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_critical[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].e_field_dreicer[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: J.m^-3\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].energy_density_kinetic[:].values\nOne scalar value is provided per element in the grid subset.Units: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_avalanche[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: kg.m^-1.s^-1\nData Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].momentum_critical_hot_tail[:].values\nOne scalar value is provided per element in the grid subset.Units: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"runaway_electrons.ggd_fluid[:].pitch_angle[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].pitch_angle[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ggd_fluid[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.current_tor\nTotal runaway current (toroidal component)Units: A\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.energy_kinetic\nTotal runaway kinetic energyUnits: J\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.current_density\nRunaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_compton\nCompton source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_dreicer\nDreicer source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_hot_tail\nHot tail source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_total\nTotal source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.ddensity_dt_tritium\nTritium source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.density\nRunaway electrons densityUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.e_field_critical\nCritical electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.e_field_dreicer\nDreicer electric field (parallel to magnetic field)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.energy_density_kinetic\nRunaways kinetic mean energy densityUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.momentum_critical_avalanche\nCritical momentum for avalanche, Compton and tritiumUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.momentum_critical_hot_tail\nCritical momentum for hot tailUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.global_quantities.volume_average.pitch_angle\nAverage pitch angle of the runaways distribution function (v_parallel/|v|)Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"runaway_electrons.grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_avalanche_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.momentum_critical_hot_tail_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].current_density\nRunaways parallel current density = average(j.B) / B0, where B0 = runawayelectrons/vacuumtoroidal_field/b0Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_compton\nCompton source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_dreicer\nDreicer source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_hot_tail\nHot tail source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_total\nTotal source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].ddensity_dt_tritium\nTritium source of runaway electronsUnits: m^-3.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].density\nRunaway electrons densityUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].e_field_critical\nCritical electric fieldUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].e_field_dreicer\nDreicer electric field (parallel to B)Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].energy_density_kinetic\nRunaways kinetic mean energy densityUnits: J.m^-3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].momentum_critical_avalanche\nCritical momentum for avalanche, Compton and tritiumUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].momentum_critical_hot_tail\nCritical momentum for hot tailUnits: kg.m^-1.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].pitch_angle\nAverage pitch angle of the runaways distribution function (v_parallel/|v|)Data Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.d\nEffective diffusivityUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.flux\nFluxUnits: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.profiles_1d[:].transport_perpendicular.v\nEffective convectionUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"runaway_electrons.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: runaway_electrons.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.crash_trigger\nFlag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition N as follows. 1: crash triggered by the ideal kink criterion; 2: crash triggered by the ideal kink criterion including kinetic effects from fast particles; 31: crash triggered by the resistive kink criterion (meeting necessary conditions for reconnection); 32: crash triggered by the resistive kink criterion (resistive kink mode is unstable). The distinction between 31 and 32 only indicates whether (31) or (32) was the last criterion to be satisfiedData Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.magnetic_shear_q1\nMagnetic shear at surface q = 1, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_crash_time\nTime at which the previous sawtooth crash occuredUnits: s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_crash_trigger\nPrevious crash trigger. Flag indicating whether a crash condition has been satisfied : 0 = no crash. N(>0) = crash triggered due to condition NData Type: INT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.previous_period\nPrevious sawtooth periodUnits: s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_inversion\nNormalised toroidal flux coordinate at inversion radiusData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_mixing\nNormalised toroidal flux coordinate at mixing radiusData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.diagnostics.rho_tor_norm_q1\nNormalised toroidal flux coordinate at surface q = 1Data Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].conductivity_parallel\nParallel conductivityUnits: ohm^-1.m^-1\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].e_field_parallel\nParallel electric field = average(E.B) / B0, where CoreProfiles/VacuumToroidal_Field/ B0Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_bootstrap\nBootstrap current density = average(JBootstrap.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_non_inductive\nNon-inductive (includes bootstrap) parallel current density = average(jni.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_ohmic\nOhmic parallel current density = average(JOhmic.B) / B0, where B0 = CoreProfiles/VacuumToroidalField/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_tor\nTotal toroidal current density = average(J_Tor/R) / average(1/R)Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].j_total\nTotal parallel current density = average(jtot.B) / B0, where B0 = CoreProfiles/VacuumToroidal_Field/ B0Units: A/m^2\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].magnetic_shear\nMagnetic shear, defined as rhotor/q . dq/drhotorData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].momentum_tor\nTotal plasma toroidal momentum, summed over ion species and electrons Units: kg.m/s\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_e\nElectron density (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_e_fast\nDensity of fast (non-thermal) electronsUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e\nElectron pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e_fast_parallel\nFast (non-thermal) electron parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_e_fast_perpendicular\nFast (non-thermal) electron perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total\nTotal ion pressure (sum over the ion species)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total_fast_parallel\nFast (non-thermal) total ion (sum over the ion species) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].p_i_total_fast_perpendicular\nFast (non-thermal) total ion (sum over the ion species) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].phi\nToroidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_parallel\nTotal parallel pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_perpendicular\nTotal perpendicular pressure (electrons+ions, thermal+non-thermal)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].pressure_thermal\nThermal pressure (electrons+ions)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].psi_star_post_crash\nPsi* = psi - phi, after the sawtooth crashUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].psi_star_pre_crash\nPsi* = psi - phi, just before the sawtooth crashUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].q\nSafety factorData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].t_e\nElectron temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].t_i_average\nIon temperature (averaged on charge states and ion species)Units: eV\nData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.profiles_1d[:].zeff\nEffective chargeData Type: FLT_1D\nCoordinates: [\"sawteeth.profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"sawteeth.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: sawteeth.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].brightness.data\nDataUnits: W.m^-2.sr^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"soft_x_rays.channel[:].brightness.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].brightness.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].energy_band[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].energies\nArray of discrete energy values inside the bandUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].lower_bound\nLower bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].energy_band[:].upper_bound\nUpper bound of the energy bandUnits: eV\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"soft_x_rays.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: soft_x_rays.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.bucked\nFlag indicating if center stack elements bucked to one anotherData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.oh\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.pl\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.displacement.tf\nRadial displacementUnits: m\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_oh\nRadial coordinate in OH layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_pl\nRadial coordinate in plug layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.grid.r_tf\nRadial coordinate in TF layerUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.noslip\nFlag indicating if center stack elements are not allowed to slip with respect to one anotherData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.plug\nFlag indicating if center stack has a plugData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.oh\nChange in shape for OH structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.pl\nChange in shape for plug structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.poisson_ratio.tf\nChange in shape for TF structural material due to applied stressData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.oh\nMaximum stress OH can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.pl\nMaximum stress plug can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.yield_strength.tf\nMaximum stress TF can withstand without permanent deformationUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.oh\nStiffness of OH structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.pl\nStiffness of plug structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.properties.young_modulus.tf\nStiffness of TF structural materialUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.oh\nAverage axial stress for OH layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.pl\nAverage axial stress for plug layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.axial.tf\nAverage axial stress for TF layer in center stackUnits: Pa\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.oh\nHoop stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.pl\nHoop stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.hoop.tf\nHoop stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.oh\nRadial stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.pl\nRadial stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.radial.tf\nRadial stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.oh\nVon Mises stresses OH layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_oh\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.pl\nVon Mises stresses plug layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_pl\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.center_stack.stress.vonmises.tf\nVon Mises stresses TF layerUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"solid_mechanics.center_stack.grid.r_tf\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: solid_mechanics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].a\nAtomic mass measured by this channelUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].current\nCollected currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].photomultiplier_voltage\nVoltage applied to the photomultiplierUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].pressure_partial\nPartial pressure (calibrated data)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].time\nTimebase for the dynamic nodes of this channelUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].validity\nIndicator of the validity of the data. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.channel[:].validity_timed\nIndicator of the validity of the data for each time slice. 0: Valid from automated processing; 1: Valid and certified by the diagnostic RO; -1: Means problem identified in the data processing (request verification by the diagnostic RO); -2: Invalid data, should not be used. (Values less than -2 have a code-specific meaning.)Data Type: INT_1D\nCoordinates: [\"spectrometer_mass.channel[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_mass.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.identifier\nID of the spectrometerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.name\nName of the spectrometerData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].a\nArray of atomic massesUnits: Atomic Mass Unit\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].current\nCollected currentUnits: A\nData Type: FLT_1D\nCoordinates: [\"spectrometer_mass.residual_spectrum[:].a\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.residual_spectrum[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_mass.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].aperture[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.detector_dimensions\nTotal detector dimension in each direction (horizontal, vertical)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.pixel_dimensions\nPixel dimension in each direction (horizontal, vertical)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_layout.pixel_n\nNumber of pixels in each direction (horizontal, vertical)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_position_parameter.data\nDataUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].detector_position_parameter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].detector_position_parameter.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.curvature_radius\nCurvature radius of the spherical gratingUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.groove_density\nNumber of grooves per unit lengthUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.curvature_radius\nCurvature radius of the image surfaceUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.image_field.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].grating.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.summit.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].grating.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].intensity_spectrum.data\nDataUnits: (counts) s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_uv.channel[:].intensity_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].intensity_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.amplitude_parameter\nAmplitude of the line of sight position parameter oscillation (in case moving_mode/index = 1)Units: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.moving_mode.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.period\nPeriod of the line of sight oscillation (in case moving_mode/index = 1)Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.position_parameter.data\nDataUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.position_parameter.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.position_parameter.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].line_of_sight.second_point.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].intensity.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].processed_line[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].radiance.data\nDataUnits: m^-2.s^-1.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].processed_line[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_uv.channel[:].radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].object\nName of the object connected to the power supplyData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].supply_high_voltage[:].voltage_set.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity_timed.data\nDataData Type: INT_2D\nCoordinates: [\"spectrometer_uv.channel[:].wavelengths\", \"spectrometer_uv.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration.gain\nGainUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration.offset\nOffsetUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.channel[:].wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_uv.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue\nEtendue (geometric extent) of the optical systemUnits: m^2.sr\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_uv.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].active_spatial_resolution[:].width.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].aperture[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.circular.ellipticity\nEllipticityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.circular.radius\nRadius of the circleUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.geometry_type\nType of geometry used to describe the image (1:'outline', 2:'circular')Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].detector_image.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].detector_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue\nEtendue (geometric extent) of the channel's optical systemUnits: m^2.str\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].etendue_method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_bundle.fibre_positions.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.fibre_radius\nRadius of a single fibreUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_bundle.geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_bundle.geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.circular.ellipticity\nEllipticityData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.circular.radius\nRadius of the circleUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.geometry_type\nType of geometry used to describe the image (1:'outline', 2:'circular')Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].fibre_image.outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].fibre_image.outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_central\nCentral wavelength of the filterUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.filter.wavelength_width\nFilter transmission function width (at 90% level)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.output_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.output_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photoelectric_voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photon_count.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.photon_count.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.photon_count.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.sensitivity\nPhotoelectric sensitivity of the detector. This is the conversion factor from the received power on the detector into electric voltage depending on the wavelengthUnits: V.W^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].filter_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].filter_spectrometer.wavelengths\nArray of wavelengths for radiance calibrationUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3\nThird dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.emission_grid.grid_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.data\nInterpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector or head of an optic fibre). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phiUnits: m^-2\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.phi\nToroidal angle (oriented counter-clockwise when viewing from above) of interpolation knotsUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.r\nMajor radius of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.interpolated.z\nHeight of interpolation knotsUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.interpolated.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.voxel_map\nVoxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.Data Type: INT_3D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim1\", \"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim2\", \"spectrometer_visible.channel[:].geometry_matrix.emission_grid.dim3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.voxels_n\nNumber of voxels defined in the voxel_map.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.with_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.with_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.with_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.without_reflections.data\nThe Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to the receiver (detector or head of an optic fibre). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indicesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].geometry_matrix.without_reflections.voxel_indices\nList of voxel indices (defined in the voxel map) used in the sparse data arrayData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].geometry_matrix.without_reflections.data\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.exposure_time\nExposure timeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.grating\nNumber of grating lines per unit lengthUnits: m^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.instrument_function\nArray of Gaussian widths and amplitudes which as a sum make up the instrument function. The instrument function is the shape that would be measured by a grating spectrometer if perfectly monochromatic line emission would be used as input. F(lambda) = 1 / sqrt (2*pi) * sum( instrumentfunction(1,i) / instrumentfunction(2,i) ) * exp( -lambda^2 / (2 * instrumentfunction(2,i)^2) ) ), whereby sum( instrumentfunction(1,i) ) = 1Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.data\nDataUnits: (counts) s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.intensity_spectrum.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.data\nDataUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].intensity.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].label\nString identifying the processed line. To avoid ambiguities, the following syntax is used : element with ionization statewavelength in Angstrom (e.g. WI4000)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.data\nDataUnits: m^-2.s^-1.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].radiance.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.processed_line[:].wavelength_central\nCentral wavelength of the processed lineUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration\nRadiance calibrationUnits: m^-3.sr^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].grating_spectrometer.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_calibration_date\nDate of the radiance calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.data\nDataUnits: (photons).m^-2.s^-1.sr^-1.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.radiance_spectral.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.slit_width\nWidth of the slit (placed in the object focal plane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.gain\nGainUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration.offset\nOffsetUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelength_calibration_date\nDate of the wavelength calibration (yyyymmdd)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].grating_spectrometer.wavelengths\nMeasured wavelengthsUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_fraction\nFraction of cold neutrals for this isotope (ncoldneutrals/(ncoldneutrals+nhotneutrals))Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].cold_neutrals_temperature\nTemperature of cold neutrals for this isotopeUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].density_ratio\nRatio of the density of neutrals of this isotope over the summed neutral densities of all other isotopes described in the ../isotope arrayData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_fraction\nFraction of hot neutrals for this isotope (nhotneutrals/(ncoldneutrals+nhotneutrals))Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].hot_neutrals_temperature\nTemperature of hot neutrals for this isotopeUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].label\nString identifying the species (H, D, T, He3, He4)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.isotope[:].time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.method.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.signal_to_noise\nLog10 of the ratio of the powers in two bands, one with the spectral lines of interest (signal) the other without spectral lines (noise).Units: dB\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.validity\nIndicator of the validity of the isotope ratios for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].isotope_ratios.validity_timed\nIndicator of the validity of the isotope ratios as a function of time (0 means valid, negative values mean non-valid)Data Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].isotope_ratios.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.positions.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].light_collection_efficiencies.values\nValues of the light collection efficienciesData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].light_collection_efficiencies.positions.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].object_observed\nMain object observed by the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].back_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].front_surface.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].geometry.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].geometry.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.extinction_coefficient\nExtinction coefficient (for metal)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.refractive_index\nRefractive index (for metal and dielectric)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.roughness\nRoughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly roughData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.transmission_coefficient\nTransmission coefficient (for dielectric)Data Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].material_properties.wavelengths\nWavelengths array for refractiveindex, extinctioncoefficient and transmission_coefficientUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].thickness\nDistance between frontsurface and backsurface along the X3 vectorUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].optical_element[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.b_field_modulus\nModulus of the magnetic field (always positive, irrespective of the sign convention for the B-field direction), obtained from Zeeman effect fitUnits: T\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_r\nLower Hybrid electric field component in the major radius directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_tor\nLower Hybrid electric field component in the toroidal directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.e_field_lh_z\nLower Hybrid electric field component in the vertical directionUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.n_e\nElectron density, obtained from Stark broadening fitUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.temperature_cold_neutrals\nFit of cold neutrals temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.temperature_hot_neutrals\nFit of hot neutrals temperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.time\nTimebase for dynamic quantities at this level of the data structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.velocity_cold_neutrals\nProjection of the cold neutral velocity along the line of sight, positive when going from first point to second point of the line of sightUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarization_spectroscopy.velocity_hot_neutrals\nProjection of the hot neutral velocity along the line of sight, positive when going from first point to second point of the line of sightUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarization_spectroscopy.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_visible.channel[:].polarizer.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].polarizer_active\nIndicator of whether a polarizer is present and active in the optical system (set to 1 in this case, set to 0 or leave empty ottherwise)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity\nIndicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity_timed.data\nDataData Type: INT_1D\nCoordinates: [\"spectrometer_visible.channel[:].validity_timed.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.channel[:].validity_timed.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_visible.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.detector_layout\nLayout of the detector grid employed. Ex: '4x16', '4x32', '1x18'Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_visible.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.geometry_type\nType of geometry used to describe the surface of the detector or aperture (1:'outline', 2:'circular', 3:'rectangle'). In case of 'outline', the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of 'circular', the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of 'rectangle', the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].aperture.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.radius\nRadius of the circle, used only if geometry_type = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.surface\nSurface of the detector/aperture, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x1_width\nFull width of the aperture in the X1 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x2_width\nFull width of the aperture in the X2 direction, used only if geometry_type = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].aperture.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.centre\nCentre (in terms of absolute wavelength) of instrument functionUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.intensity\nScaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detectorUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.scale\nScale of Lorentzian instrument function (full width at half height)Units: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.sigma\nStandard deviation of Gaussian instrument functionUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.values\nExplicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a binned pixel of the detector, gives the detector pixel output in counts/seconds.Units: sr.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].instrument_function.wavelengths\nArray of wavelengths on which the instrument function is definedUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].wavelength\nWavelength of incoming photons on each horizontal pixel of this bin.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].bin[:].z_pixel_range\nVertical pixel index range indicating the corresponding binned detector areaData Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.camera_dimensions\nTotal camera dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.identifier\nID of the cameraData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.first_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.line_of_sight.second_point.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_dimensions\nPixel dimension in each direction (x1, x2)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixel_position.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.pixels_n\nNumber of pixels in each direction (x1, x2)Data Type: INT_1D\nCoordinates: [\"1...2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].camera.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.angle_bragg\nBragg angle of the crystalUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.cut\nMiller indices characterizing the cut of the crystal (can be of length 3 or 4)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.identifier\nID of the objectData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.mesh_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].crystal.outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.surface\nSurface of the object, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.thickness\nThickness of the crystalUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.wavelength_bragg\nBragg wavelength of the crystalUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x1_width\nFull width of the object in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x2_width\nFull width of the object in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].crystal.x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].detection_efficiency\nProbability of detection of a photon impacting the detector as a function of its energy Data Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].energies\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energies\nArray of energy values for tabulation of the detection efficiencyUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energy_bound_lower\nLower energy bound for the photon detection, for each pixel (horizontal, vertical)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].energy_bound_upper\nUpper energy bound for the photon detection, for each pixel (horizontal, vertical)Units: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].exposure_time\nExposure time of the measurementUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].identifier\nID of the filterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].filter_window[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].photon_absorption\nProbability of absorbing a photon passing through the filter as a function of its wavelength Data Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].surface\nSurface of the filter, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].thickness\nThickness of the filter windowUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_lower\nLower bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelength_upper\nUpper bound of the filter wavelength rangeUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].wavelengths\nArray of wavelength valuesUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x1_width\nFull width of the filter in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x2_width\nFull width of the filter in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].filter_window[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].counts_bin_n\nNumber of counts detected on each pixel/bin of the binned frame during one exposure timeData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].bin\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].counts_n\nNumber of counts detected on each pixel of the frame during one exposure timeData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].frame[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.centre\nCentre (in terms of absolute wavelength) of instrument functionUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.intensity\nScaling factor for the instrument function such that convolving the instrument function with an emission spectrum gives the counts per second on the detectorUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.scale\nScale of Lorentzian instrument function (full width at half height)Units: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.sigma\nStandard deviation of Gaussian instrument functionUnits: m\nData Type: FLT_2D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.values\nExplicit instrument function values for the detector. When multiplied by the line-integrated emission spectrum in photons/second/sr/m/m^2 received on a pixel of the detector, gives the detector pixel output in counts/seconds.Units: sr.m\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\", \"spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].instrument_function.wavelengths\nArray of wavelengths on which the instrument function is definedUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.data\nDataData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_rho_tor_norm.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.lines_of_sight_second_point.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.data\nDataUnits: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_e.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.data\nDataUnits: eV\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.t_i.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\nTimebase for the dynamic nodes of this probe located at this level of the IDS structureUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.data\nDataUnits: m.s^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity\nIndicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.velocity_tor.validity_timed\nIndicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity)Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].profiles_line_integrated.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].centre.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].curvature_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].identifier\nID of the objectData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].material.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1\nPositions along x1 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x2\nPositions along x2 axisUnits: m\nData Type: FLT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.channel[:].reflector[:].outline.x1\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].radius\nRadius of the circle, used only if geometry_type/index = 2Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].surface\nSurface of the object, derived from the above geometric dataUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_curvature\nRadius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x1_width\nFull width of the object in the X1 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_curvature\nRadius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x2_width\nFull width of the object in the X2 direction, used only if geometry_type/index = 3Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].reflector[:].x3_unit_vector.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].wavelength_frames\nWavelength of incoming photons on each pixel of the frames, mainly varying accross the horizontal dimension of the frame. However a 2D map of the wavelength is given since it is not constant vertically due to the elliptical curvature of the photon iso-surfacesUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"spectrometer_x_ray_crystal.channel[:].z_frames\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.channel[:].z_frames\nHeight of the observed zone at the focal plane in the plasma, corresponding to the vertical dimension of the frameUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spectrometer_x_ray_crystal.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spectrometer_x_ray_crystal.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_r\nMajor radius component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_tor\nToroidal component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].velocity_z\nVertical component of the fragment velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragment[:].volume\nVolume of the fragmentUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.atoms_n\nTotal number of atoms of the gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.flow_rate\nFlow rate of the gas at the injector exitUnits: atoms.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].fraction\nAtomic fraction of the speciesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].fragmentation_gas.temperature\nGas temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].identifier\nIdentifier of the injectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].injection_direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].name\nName of the injectorData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].optical_pellet_diagnostic.time_arrival\nArrival time at the optical pellet diagnostic, for each objectUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.atoms_n\nTotal number of atoms of desublimated gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.core.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.diameter\nPellet diameterUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.length\nPellet length (cylindrical pellet)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.atoms_n\nTotal number of atoms of desublimated gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].density\nDensity of the speciesUnits: atoms.m^-3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.shell.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_r\nMajor radius component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_shatter\nNorm of the velocity of the centre of mass of the pellet right before shatteringUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_tor\nToroidal component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].pellet.velocity_z\nVertical component of the velocity of the centre of mass of the pelletUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.atoms_n\nTotal number of atoms of the gasUnits: atoms\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.flow_rate\nFlow rate of the gas at the injector exitUnits: atoms.s^-1\nData Type: FLT_1D\nCoordinates: [\"spi.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].fraction\nAtomic fraction of the speciesData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].label\nString identifying the species (e.g. H, D, T, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.species[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].propellant_gas.temperature\nGas temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.angle_major\nAngle between the cone direction and unitvectormajorUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.angle_minor\nAngle between the cone direction and unitvectorminorUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.direction.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.origin.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_major.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.x\nComponent along X axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.y\nComponent along Y axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shatter_cone.unit_vector_minor.z\nComponent along Z axisUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_angle\nImpact (or grazing) angle of the pellet with the shattering element. It is the complementary of the incidence angle with the element surface at the shattering locationUnits: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].shattering_position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].time_shatter\nArrival time at the shattering unitUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].time_trigger\nTime of trigger request to the power supply according to the DMS sequenceUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_r\nMajor radius component of the velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_tor\nToroidal component of the velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.injector[:].velocity_mass_centre_fragments_z\nVertical component of the velocity velocity of the centre of mass of the fragments at the shattering cone originUnits: m.s^-1\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.shatter_cone_definition.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: spi.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.all_cleared\nTrue (1) if all stability limits are cleared, otherwise False (0)Data Type: INT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.collection[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].cleared\nTrue (1) if a given stability limit is cleared, otherwise False (0)Data Type: INT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].fraction\nFraction of limit Data Type: FLT_1D\nCoordinates: [\"stability.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.model[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: stability.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.distance_inner_outer_separatrices.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.distance_inner_outer_separatrices.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.elongation.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.elongation.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.gap_limiter_wall.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.gap_limiter_wall.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.geometric_axis_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.magnetic_axis_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.minor_radius.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.minor_radius.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_configuration.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_configuration.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_inner_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_r.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_r.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_z.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.strike_point_outer_z.value\nValueUnits: m\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.triangularity_lower.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.boundary.triangularity_lower.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.ip.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.exponential.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_magnetic_axis.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.exponential.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.exponential.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_20_80.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_20_80.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.decay_times.t_e_volume_average.linear_custom.decay_time.value\nValueUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.mitigation_valve.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.mitigation_valve.value\nValueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.disruption.time.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.a.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.a.value\nValueUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.label.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.label.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.z_n.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].species.z_n.value\nValueUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].tangency_radius.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.nbi[:].tangency_radius.value\nValueUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_additional.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_additional.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ec.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ec.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_ic.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ec.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ec.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_ic.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_lh.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_lh.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi_co_injected_ratio.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_nbi_co_injected_ratio.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_launched_total.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_lh.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_lh.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_nbi.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.heating_current_drive.power_nbi.value\nValueUnits: W\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.kicks.occurrence.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.kicks.occurrence.value\nValueData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.iron.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.lithium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.lithium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.neon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.neon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.deuterium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.helium_4.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.hydrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.iron.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.krypton.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.lithium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.lithium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.neon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.neon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.nitrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.oxygen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tritium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.itb.velocity_tor.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.carbon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.deuterium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.deuterium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_3.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.helium_4.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.hydrogen.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.iron.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.magnetic_axis.velocity_tor.krypton.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.pedestal.q.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.helium_4.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.position.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.q.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.q.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_e.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_i_average.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.t_i_average.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.argon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.argon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.beryllium.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.local.separatrix_average.velocity_tor.carbon.value\nValueUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.dn_e_dt.value\nValueUnits: m^-3.s-1\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.isotope_fraction_hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.isotope_fraction_hydrogen.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.meff_hydrogenic.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.meff_hydrogenic.value\nValueUnits: amu\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_e.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.argon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.beryllium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.beryllium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.carbon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.carbon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.deuterium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.deuterium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_3.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_3.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_4.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.helium_4.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.hydrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.hydrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.iron.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.iron.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.krypton.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.krypton.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.neon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.nitrogen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.nitrogen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.oxygen.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.oxygen.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tritium.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tritium.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tungsten.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.tungsten.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.xenon.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i.xenon.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i_total.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.n_i_total.value\nValueUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_e.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_e.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_i_average.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.t_i_average.value\nValueUnits: eV\nData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.zeff.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.volume_average.zeff.value\nValueData Type: FLT_1D\nCoordinates: [\"summary.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.evaporation.source\nSource of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.evaporation.value\nValueData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.material.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: summary.wall.material.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
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    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float4d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].value.data\nDataUnits: mixed\nData Type: FLT_5D\nCoordinates: [\"1...N\", \"1...N\", \"1...N\", \"1...N\", \"temporary.dynamic_float5d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float5d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].value.data\nDataUnits: mixed\nData Type: FLT_6D\nCoordinates: [\"1...N\", \"1...N\", \"1...N\", \"1...N\", \"1...N\", \"temporary.dynamic_float6d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_float6d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].value.data\nDataData Type: INT_1D\nCoordinates: [\"temporary.dynamic_integer1d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer1d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].value.data\nDataData Type: INT_2D\nCoordinates: [\"1...N\", \"temporary.dynamic_integer2d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer2d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].value.data\nDataData Type: INT_3D\nCoordinates: [\"1...N\", \"1...N\", \"temporary.dynamic_integer3d[:].value.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.dynamic_integer3d[:].value.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: temporary.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.b_field_tor_vacuum_r.data\nDataUnits: T.m\nData Type: FLT_1D\nCoordinates: [\"tf.b_field_tor_vacuum_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.b_field_tor_vacuum_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"tf.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_phi\nToroidal angles (relative to a reference point)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].cross_section.delta_r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_r\nMajor radii (relative to a reference point)Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].cross_section.delta_z\nHeights (relative to a reference point)Units: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].cross_section.delta_r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.centres.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.centres.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.centres.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.end_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.end_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.end_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.intermediate_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.intermediate_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.intermediate_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.names\nName or description of every elementData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.start_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.start_points.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.start_points.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].elements.types\nType of every element: 1: line segment, its ends are given by the start and end points; index = 2: arc of a circle; index = 3: full circleData Type: INT_1D\nCoordinates: [\"tf.coil[:].conductor[:].elements.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].resistance\nconductor resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].conductor[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].conductor[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].current.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].current.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].current.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].identifier\nAlphanumeric identifier of coil used for convenienceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].name\nName of the coilData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].resistance\nCoil resistanceUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].turns\nNumber of total turns in a toroidal field coil. May be a fraction when describing the coil connections.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].voltage.data\nDataUnits: V\nData Type: FLT_1D\nCoordinates: [\"tf.coil[:].voltage.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coil[:].voltage.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.coils_n\nNumber of coils around the torus, in case is_periodic = 1Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.delta_b_field_tor_vacuum_r.data\nDataUnits: T.m\nData Type: FLT_1D\nCoordinates: [\"tf.delta_b_field_tor_vacuum_r.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.delta_b_field_tor_vacuum_r.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].a_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].a_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_r[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_r[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_tor[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_tor[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: FLT_2D\nCoordinates: [\"tf.field_map[:].b_field_z[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].b_field_z[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"tf.field_map[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.field_map[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.is_periodic\nFlag indicating whether coils are described one by one in the coil() structure (flag=0) or whether the coil structure represents only coils having different characteristics (flag = 1, n_coils must be filled in that case). In the latter case, the coil() sequence is repeated periodically around the torus.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.latency\nUpper bound of the delay between input command received from the RT network and actuator starting to react. Applies globally to the system described by this IDS unless specific latencies (e.g. channel-specific or antenna-specific) are provided at a deeper level in the IDS structure.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.r0\nReference major radius of the device (from the official description of the device). This node is the placeholder for this official machine description quantity (typically the middle of the vessel at the equatorial midplane, although the exact definition may depend on the device)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: tf.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.time\nTime for the R,Z,phi coordinatesUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].delta_position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].delta_position.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].distance_separatrix_midplane.data\nDataUnits: m\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].distance_separatrix_midplane.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].distance_separatrix_midplane.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].identifier\nID of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].n_e.data\nDataUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].n_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].n_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].name\nName of the channelData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.phi\nToroidal angle (oriented counter-clockwise when viewing from above)Units: rad\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.r\nMajor radiusUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].position.z\nHeightUnits: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].t_e.data\nDataUnits: eV\nData Type: FLT_1D\nCoordinates: [\"thomson_scattering.channel[:].t_e.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.channel[:].t_e.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"thomson_scattering.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.machine\nName of the experimental device to which this data is relatedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.pulse\nPulse numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.pulse_type\nType of the data entry, e.g. \"pulse\", \"simulation\", ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.run\nRun numberData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.data_entry.user\nUsernameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.name\nIDS nameData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.equilibrium_id.occurrence\nIDS occurrenceData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.latency\nUpper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.Units: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.midplane.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: thomson_scattering.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].current.value\nValue of the boundary condition. For ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].electrons.particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].energy_ion_total.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].energy.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].particles.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.rho_tor_norm\nPosition, in normalised toroidal flux, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed.Data Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].momentum_tor.value\nValue of the boundary condition. For ID = 1 to 4, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].current[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].electrons.particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"transport_solver_numerics.boundary_conditions_ggd[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].energy[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].particles[:].values\nList of vector components, one list per element in the grid subset. First dimenstion: element index. Second dimension: vector component index (for ID = 1 to 3, only the first position in the vector is used. For ID = 5, all three positions are used, meaning respectively a1, a2, a3)Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.boundary_conditions_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"transport_solver_numerics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].current.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].electrons.particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].energy_ion_total.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].energy.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].particles.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.equations[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.time_step.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.convergence.time_step.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.convergence.time_step.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2_drho_tor_norm2.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d2psi_drho_tor2\nSecond derivative of the poloidal flux profile with respect to the toroidal flux coordinateUnits: Wb.m^-2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_drho_tor_norm.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dt.n_i_total_over_n_e\nRatio of total ion density (sum over species and charge states) over electron density. (thermal+non-thermal)Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dt.pressure_ion_total\nTotal thermal ion pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].d_dvolume_drho_tor_dt\nPartial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinateUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_drho_tor\nDerivative of the poloidal flux profile with respect to the toroidal flux coordinateUnits: Wb.m^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt\nDerivative of the poloidal flux profile with respect to timeUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt_cphi\nDerivative of the poloidal flux profile with respect to time, at constant toroidal fluxUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].dpsi_dt_crho_tor_norm\nDerivative of the poloidal flux profile with respect to time, at constant normalised toroidal flux coordinateUnits: V\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].drho_tor_dt\nPartial derivative of the toroidal flux coordinate profile with respect to timeUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d2_drho_tor_norm2.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_drho_tor_norm.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].electrons.d_dt.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d2_drho_tor_norm2.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_drho_tor_norm.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.density_fast\nDensity of fast (non-thermal) particles (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure\nPressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressure (average over charge states when multiple charge states are considered)Units: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_pol\nPoloidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].d_dt.velocity_tor\nToroidal velocity (average over charge states when multiple charge states are considered)Units: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d2_drho_tor_norm2.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_drho_tor_norm.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.density_fast\nDensity of fast (non-thermal) particlesUnits: m^-3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure\nPressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_parallel\nFast (non-thermal) parallel pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.pressure_fast_perpendicular\nFast (non-thermal) perpendicular pressureUnits: Pa\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.temperature\nTemperatureUnits: eV\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_pol\nPoloidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].d_dt.velocity_tor\nToroidal velocityUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.derivatives_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].is_neutral\nFlag specifying if this state corresponds to a neutral (1) or not (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].ion[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.derivatives_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.primary_coordinate.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].descriptions\nDescriptions of the restart filesData Type: STR_1D\nCoordinates: [\"transport_solver_numerics.restart_files[:].names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].names\nNames of the restart filesData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.restart_files[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].name\nName of the control parameterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.integer0d[:].value\nValue of the control parameterData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].name\nName of the control parameterData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].control_parameters.real0d[:].value\nValue of the control parameterUnits: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].d_dvolume_drho_tor_dt\nPartial derivative with respect to time of the derivative of the volume with respect to the toroidal flux coordinateUnits: m^2.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].drho_tor_dt\nPartial derivative of the toroidal flux coordinate profile with respect to timeUnits: m.s^-1\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].position\nPosition, in terms of the primary coordinate, at which the boundary condition is imposed. Outside this position, the value of the data are considered to be prescribed (in case of a single boundary condition).Units: mixed\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].boundary_condition[:].value\nValue of the boundary condition. For type/index = 1 to 3, only the first position in the vector is used. For type/index = 5, all three positions are used, meaning respectively a1, a2, a3. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...3\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].coefficient[:].profile\nRadial profile of the numerical coefficientUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].computation_mode.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.expression\nExpression used by the solver to calculate the relative deviationData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.delta_relative.value\nValue of the relative deviationData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].convergence.iterations_n\nNumber of iterations carried out in the convergence loopData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d2_dr2\nSecond order radial derivative with respect to the primary coordinateUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dr\nRadial derivative with respect to the primary coordinateUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt\nTime derivativeUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cphi\nDerivative with respect to time, at constant toroidal flux (for current diffusion equation)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.d_dt_cr\nDerivative with respect to time, at constant primary coordinate coordinate (for current diffusion equation)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.ion_index\nIf the primary quantity is related to a ion species, index of the corresponding species in the coreprofiles/profiles1d/ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.neutral_index\nIf the primary quantity is related to a neutral species, index of the corresponding species in the coreprofiles/profiles1d/neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.profile\nProfile of the primary quantityUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].equation[:].primary_quantity.state_index\nIf the primary quantity is related to a particular state (of an ion or a neutral species), index of the corresponding state in the coreprofiles/profiles1d/ion (or neutral)/state arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.solver_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.solver_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_average.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step_average.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_average.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_min.data\nDataUnits: s\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time_step_min.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.time_step_min.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"transport_solver_numerics.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: transport_solver_numerics.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"turbulence.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].dim1\nFirst dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].dim2\nSecond dimension valuesUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.grid_2d_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.density\nDensity (thermal+non-thermal)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.density_thermal\nDensity of thermal particlesUnits: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].electrons.temperature\nTemperatureUnits: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed), volume averaged over plasma radiusUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].density\nDensity (thermal+non-thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].density_thermal\nDensity (thermal) (sum over charge states when multiple charge states are considered)Units: m^-3\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].label\nString identifying ion (e.g. H+, D+, T+, He+2, C+, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].neutral[:].temperature\nTemperature (average over charge states when multiple charge states are considered)Units: eV\nData Type: FLT_2D\nCoordinates: [\"turbulence.grid_2d[:].dim1\", \"turbulence.grid_2d[:].dim2\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: turbulence.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].component_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].identifier\nIdentifier of this unit. Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : ic_antenna/a1/bumpers refers to the bumpers of the a1 IC antennaData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].name\nName of the limiter unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].limiter.unit[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].phi_extensions\nSimplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].limiter.unit[:].resistivity\nResistivity of the limiter unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].name\nName of the mobile unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].outline[:].z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].mobile.unit[:].outline[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].phi_extensions\nSimplified description of toroidal angle extensions of the unit, by a list of zones defined by their centre and full width (in toroidal angle). In each of these zones, the unit outline remains the same. Leave this node empty for an axisymmetric unit. The first dimension gives the centre and full width toroidal angle values for the unit. The second dimension represents the toroidal occurrences of the unit countour (i.e. the number of toroidal zones).Units: rad\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].mobile.unit[:].resistivity\nResistivity of the mobile unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.centreline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_inner.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.outline_inner.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.outline_outer.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.outline_outer.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.resistivity\nResistivity of the vessel unitUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].annular.thickness\nThickness of the vessel layer in the perpendicular direction to the centreline. Thickness(i) is the thickness of the layer between centreline/r(i),z(i) and centreline/r(i+1),z(i+1)Units: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].annular.centreline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].j_tor.data\nDataUnits: A\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].element[:].j_tor.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].j_tor.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].name\nName of the block elementData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.closed\nFlag identifying whether the contour is closed (1) or open (0)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].outline.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"wall.description_2d[:].vessel.unit[:].element[:].outline.r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].resistance\nResistance of the block elementUnits: Ohm\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].element[:].resistivity\nResistivity of the block elementUnits: ohm.m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].identifier\nIdentifier of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_2d[:].vessel.unit[:].name\nName of the unitData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].identifiers\nIdentifiers of the components (described in the various gridsubsets). Although the details may be machine-specific, a tree-like syntax must be followed, listing first top level components, then going down to finer element description. The tree levels are separated by a /, using a number of levels relevant to the granularity of the description. Example : icantenna/a1/bumpers refers to the bumpers of the a1 IC antennaData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].component[:].type[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].a_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: T.m\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].a_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].a_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T.m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].e_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].e_field[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].e_field[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.current.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.electrons.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.kinetic.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.radiation.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].energy_fluxes.recombination.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].r\nComponent along the major radius axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].r_coefficients\nInterpolation coefficients for the component along the major radius axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].toroidal\nToroidal component, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].j_total[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].toroidal_coefficients\nInterpolation coefficients for the toroidal component, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].z\nComponent along the height axis, one scalar value is provided per element in the grid subset.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].ggd[:].j_total[:].r\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].j_total[:].z_coefficients\nInterpolation coefficients for the component along the height axis, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.electrons.incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].emitted[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m^-2.s^-1\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].incident[:].values\nOne scalar value is provided per element in the grid subset.Units: m^-2.s^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].particle_fluxes.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].phi_potential[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].phi_potential[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: W.m^-2\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].power_density[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].power_density[:].values\nOne scalar value is provided per element in the grid subset.Units: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Wb\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].psi[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].psi[:].values\nOne scalar value is provided per element in the grid subset.Units: Wb\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].label\nString identifying ion (e.g. H, D, T, He, C, D2, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].multiple_states_flag\nMultiple states calculation flag : 0-Only the 'ion' level is considered and the 'state' array of structure is empty; 1-Ion states are considered and are described in the 'state' array of structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].neutral_index\nIndex of the corresponding neutral species in the ../../neutral arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_max\nMaximum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].state[:].z_min\nMinimum Z of the charge state bundleUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].ion_index\nIndex of the corresponding ion species in the ../../ion arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].label\nString identifying neutral (e.g. H, D, T, He, C, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].multiple_states_flag\nMultiple states calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Data Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].coefficient[:].values\nOne scalar value is provided per element in the grid subset.Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].label\nString identifying stateData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].neutral_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].recycling.neutral[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: Ohm.m\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].resistivity[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].resistivity[:].values\nOne scalar value is provided per element in the grid subset.Units: Ohm.m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: K\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].temperature[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].temperature[:].values\nOne scalar value is provided per element in the grid subset.Units: K\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].ggd[:].v_biasing[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].ggd[:].v_biasing[:].values\nOne scalar value is provided per element in the grid subset.Units: V\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"wall.description_ggd[:].grid_ggd[:].grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: IDS::wall/0/descriptionggd(1)/gridggd, means that the grid is located in the wall IDS, occurrence 0, with relative path descriptionggd(1)/gridggd, using Fortran index convention (here : first index of the array)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].grid_ggd[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.descriptions\nVerbose descriptionData Type: STR_1D\nCoordinates: [\"wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.indices\nInteger identifiers (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_1D\nCoordinates: [\"wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].grid_subset[:].identifiers.names\nShort string identifiersData Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].material[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: m\nData Type: FLT_2D\nCoordinates: [\"wall.description_ggd[:].thickness[:].grid_subset[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].grid_subset[:].values\nOne scalar value is provided per element in the grid subset.Units: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].thickness[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.description_ggd[:].type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_enclosed_volume\nVolume available to gas or plasma enclosed by the first wall contourUnits: m^3\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_power_flux_peak.data\nDataUnits: W.m^-2\nData Type: FLT_1D\nCoordinates: [\"wall.first_wall_power_flux_peak.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_power_flux_peak.time\nTimeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.first_wall_surface_area\nFirst wall surface areaUnits: m^2\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.current_tor\nToroidal current flowing in the vacuum vesselUnits: A\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.gas_puff\nGas puff rate (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.particle_flux_from_plasma\nParticle flux from the plasma (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.particle_flux_from_wall\nParticle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), in equivalent electronsUnits: s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.power_inner_target\nElectron power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.power_outer_target\nElectron power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.electrons.pumping_speed\nPumped particle flux (in equivalent electrons)Units: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].gas_puff\nGas puff rate for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].energies\nArray of energies of this incident species, on which the sputteringphysicalcoefficient is tabulatedUnits: eV\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].label\nString identifying the incident species (e.g. H, D, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].sputtering_chemical_coefficient\nEffective coefficient of chemical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident speciesData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].incident_species[:].sputtering_physical_coefficient\nEffective coefficient of physical sputtering for various neutral types (first dimension: 1: cold; 2: thermal; 3: fast), due to this incident species and for various energies (second dimension)Data Type: FLT_3D\nCoordinates: [\"1...3\", \"wall.global_quantities.neutral[:].incident_species[:].energies\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].label\nString identifying the species (e.g. H, D, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].particle_flux_from_plasma\nParticle flux from the plasma for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].particle_flux_from_wall\nParticle flux from the wall corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Units: s^-1\nData Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].pumping_speed\nPumped particle flux for that speciesUnits: s^-1\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].recycling_energy_coefficient\nEnergy recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Data Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].recycling_particles_coefficient\nParticle recycling coefficient corresponding to the conversion into various neutral types (first dimension: 1: cold; 2: thermal; 3: fast)Data Type: FLT_2D\nCoordinates: [\"1...3\", \"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.neutral[:].wall_inventory\nWall inventory, i.e. cumulated exchange of neutral species between plasma and wall from t = 0, positive if a species has gone to the wall, for that speciesData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_black_body\nBlack body radiated power emitted from the wall (emissivity is included)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_conducted\nPower conducted by the plasma onto the wallUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_convected\nPower convected by the plasma onto the wallUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_currents\nPower deposited on the wall due to electric currents (positive means power is deposited on the target)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_density_inner_target_max\nMaximum power density on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_density_outer_target_max\nMaximum power density on the outer targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_incident\nTotal power incident on the wall. This power is split in the various physical categories listed belowUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_inner_target_ion_total\nTotal ion (summed over ion species) power on the inner targetUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_neutrals\nNet power from neutrals on the wall (positive means power is deposited on the wall)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_radiated\nNet radiated power from plasma onto the wall (incident-reflected)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_recombination_neutrals\nPower deposited on the wall due to recombination of neutrals into a ground state (e.g. molecules)Units: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_recombination_plasma\nPower deposited on the wall due to recombination of plasma ionsUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.power_to_cooling\nPower to cooling systemsUnits: W\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.global_quantities.temperature\nWall temperatureUnits: K\nData Type: FLT_1D\nCoordinates: [\"wall.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.temperature_reference.data\nReference temperatureUnits: K\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.temperature_reference.description\nDescription of how the reference temperature is defined : for which object, at which location, ...Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: wall.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.minus.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.parallel.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.imaginary\nImaginary partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].e_field.plus.real\nReal partUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].electrons.power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].power\nPower absorbed along the beam by the speciesUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].length\nRay/beam curvilinear lengthUnits: m\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].phase.angle\nRotation angle for the phase ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].phase.curvature\nInverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)Units: m^-1\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.phi\nToroidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.psi\nPoloidal fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.theta\nPoloidal angleUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].position.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.parallel\nNormalized power flow in the direction parallel to the magnetic fieldData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_flow_norm.perpendicular\nNormalized power flow in the direction perpendicular to the magnetic fieldData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].power_initial\nInitial power in the ray/beamUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].spot.angle\nRotation angle for the spot ellipseUnits: rad\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].spot.size\nSize of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)Units: m\nData Type: FLT_2D\nCoordinates: [\"1...2\", \"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r\nWave vector component in the major radius directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_r_norm\nNormalized wave vector component in the major radius direction = k_r / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor\nWave vector component in the toroidal directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_tor_norm\nNormalized wave vector component in the toroidal direction = k_tor / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z\nWave vector component in the vertical directionUnits: m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.k_z_norm\nNormalized wave vector component in the vertical direction = k_z / norm(k)Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_parallel\nParallel refractive indexData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_perpendicular\nPerpendicular refractive indexData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.n_tor\nToroidal wave number, contains a single value if varyingntor = 0 to avoid useless repetition constant values. The wave vector toroidal component is defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive ntor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"coherent_wave[:].beam_tracing[:].beam[:].length\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].beam[:].wave_vector.varying_n_tor\nFlag telling whether n_tor is constant along the ray path (0) or varying (1)Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].beam_tracing[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.bi_normal[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.normal[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: T\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].b_field.parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: T\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.bi_normal[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.minus[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.minus[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.normal[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.normal[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.parallel[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: CPX_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].e_field.plus[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].grid_subset_index\nIndex of the grid subset the data is provided onData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].e_field.plus[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: CPX_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].base[:].tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].dimension\nSpace dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].dimension\nDimension of the object - using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumesData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].index\nObject indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element[:].object[:].space\nIndex of the space from which that object is takenData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.jacobian\nMetric JacobianUnits: mixed\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_contravariant\nContravariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].metric.tensor_covariant\nCovariant metric tensor, given on each element of the subgrid (first dimension)Units: mixed\nData Type: FLT_3D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].grid.grid_subset[:].element\", \"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.path\nPath of the grid, including the IDS name, in case of implicit reference to a gridggd node described in another IDS. To be filled only if the grid is not described explicitly in this gridggd structure. Example syntax: 'wall:0/descriptionggd(1)/gridggd', means that the grid is located in the wall IDS, occurrence 0, with ids path 'descriptionggd(1)/gridggd'. See the link below for more details about IDS pathsData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].coordinates_type\nType of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space. The meaning of these predefined integer constants can be found in the Data Dictionary under utilities/coordinate_identifier.xmlData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].geometry_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].identifier.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].geometry_content.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].index\nIndex of this (n-1)-dimensional boundary objectData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].boundary[:].neighbours\nList of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundaryData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry\nGeometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered. Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].geometry_2d\n2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.Units: mixed\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].measure\nMeasure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,...)Units: m^dimension\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].grid.space[:].objects_per_dimension[:].object[:].nodes\nList of nodes forming this object (indices to objectsperdimension(1)%object(:) in Fortran notation)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].coefficients\nInterpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).Units: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_index\nIndex of the grid used to represent this quantityData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].grid_subset_index\nIndex of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/indexData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].k_perpendicular[:].values\nOne scalar value is provided per element in the grid subset.Units: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].full_wave[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].current_tor\nWave driven toroidal current from a stand alone calculation (not consistent with other sources)Units: A\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].current_tor_n_tor\nWave driven toroidal current from a stand alone calculation (not consistent with other sources) per toroidal mode numberUnits: A\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.distribution_assumption\nAssumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS). Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].electrons.power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].frequency\nWave frequencyUnits: Hz\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].distribution_assumption\nAssumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS). Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast\nWave power absorbed by the fast particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_fast_n_tor\nWave power absorbed by the fast particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal\nWave power absorbed by the thermal particle populationUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].power_thermal_n_tor\nWave power absorbed by the thermal particle population per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].power\nTotal absorbed wave powerUnits: W\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].power_n_tor\nAbsorbed wave power per toroidal mode numberUnits: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].global_quantities[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].global_quantities[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.antenna_name\nName of the antenna that launches this wave. Corresponds to the name specified in antennas/ec(i)/name, or antennas/ic(i)/name or antennas/lh(i)/name (depends of antenna/wave type) in the ANTENNAS IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.index_in_antenna\nIndex of the wave (starts at 1), separating different waves generated from a single antenna.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].identifier.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_parallel_density\nFlux surface averaged wave driven parallel current density = average(j.B) / B0, where B0 = vacuumtoroidalfield/b0.Units: A.m^-2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_parallel_density_n_tor\nFlux surface averaged wave driven parallel current density, per toroidal mode numberUnits: A.m^-2\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_tor_inside\nWave driven toroidal current, inside a flux surfaceUnits: A\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].current_tor_inside_n_tor\nWave driven toroidal current, inside a flux surface, per toroidal mode numberUnits: A\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].minus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].parallel.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].e_field_n_tor[:].plus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].electrons.power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi_boundary\nValue of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.psi_magnetic_axis\nValue of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn't go from the magnetic axis to the plasma boundary)Units: Wb\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_pol_norm\nNormalised poloidal flux coordinate = sqrt((psi(rho)-psi(magneticaxis)) / (psi(LCFS)-psi(magneticaxis)))Data Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_tor\nToroidal flux coordinate. rhotor = sqrt(bfluxtor/(pib0)) ~ sqrt(pir^2b0/(pib0)) ~ r [m]. The toroidal field used in its definition is indicated under vacuumtoroidal_field/b0Units: m\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see timeslice/boundary/bfluxpolnorm in the equilibrium IDS) Data Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.surface\nSurface area of the toroidal flux surfaceUnits: m^2\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast\nFlux surface averaged absorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_fast_n_tor\nFlux surface averaged absorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal\nFlux surface averaged absorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_density_thermal_n_tor\nFlux surface averaged absorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_fast_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].power_inside_thermal_n_tor\nAbsorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].k_perpendicular\nPerpendicular wave vector, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that kperpendicular = ave(kperpendicular.powerdensity) / ave(powerdensity), for every flux surface and every toroidal numberUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_density\nFlux surface averaged total absorbed wave power density (electrons + ion + fast populations)Units: W.m^-3\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_density_n_tor\nFlux surface averaged absorbed wave power density per toroidal mode numberUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_inside\nTotal absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density)Units: W\nData Type: FLT_1D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].power_inside_n_tor\nTotal absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode numberUnits: W\nData Type: FLT_2D\nCoordinates: [\"waves.coherent_wave[:].profiles_1d[:].grid.rho_tor_norm\", \"waves.coherent_wave[:].profiles_1d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_1d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].minus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].parallel.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.amplitude\nAmplitudeUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].e_field_n_tor[:].plus.phase\nPhaseUnits: V.m^-1\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].electrons.power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.area\nCross-sectional area of the flux surfaceUnits: m^2\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.psi\nPoloidal magnetic fluxUnits: Wb\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.r\nMajor radiusUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.rho_tor\nToroidal flux coordinate. The toroidal field used in its definition is indicated under vacuumtoroidalfield/b0Units: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.rho_tor_norm\nNormalised toroidal flux coordinate. The normalizing value for rhotornorm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation) Data Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.theta_geometric\nGeometrical poloidal angleUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.theta_straight\nStraight field line poloidal angleUnits: rad\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.volume\nVolume enclosed inside the magnetic surfaceUnits: m^3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].grid.z\nHeightUnits: m\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].a\nMass of atomUnits: Atomic Mass Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].atoms_n\nNumber of atoms of this element in the moleculeData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].element[:].z_n\nNuclear chargeUnits: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].label\nString identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].multiple_states_flag\nMultiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structureData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].electron_configuration\nConfiguration of atomic orbitals of this state, e.g. 1s2-2s1Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].label\nString identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, ...)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast\nAbsorbed wave power density on the fast speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_fast_n_tor\nAbsorbed wave power density on the fast species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal\nAbsorbed wave power density on the thermal speciesUnits: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].power_density_thermal_n_tor\nAbsorbed wave power density on the thermal species, per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_level\nVibrational level (can be bundled)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].vibrational_mode\nVibrational mode of this state, e.g. \"A_g\". Need to define, or adopt a standard nomenclature.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_max\nMaximum Z of the charge state bundle (equal to z_min if no bundle)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].state[:].z_min\nMinimum Z of the charge state bundle (zmin = zmax = 0 for a neutral)Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].ion[:].z_ion\nIon charge (of the dominant ionisation state; lumped ions are allowed).Units: Elementary Charge Unit\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].n_tor\nToroidal mode numbers, the wave vector toroidal component being defined as ktor = ntor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi directionData Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].power_density\nTotal absorbed wave power density (electrons + ion + fast populations)Units: W.m^-3\nData Type: FLT_2D\nCoordinates: [\"1...N\", \"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].power_density_n_tor\nAbsorbed wave power density per toroidal mode numberUnits: W.m^-3\nData Type: FLT_3D\nCoordinates: [\"1...N\", \"1...N\", \"waves.coherent_wave[:].profiles_2d[:].n_tor\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].profiles_2d[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.coherent_wave[:].wave_solver_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.magnetic_axis.r\nMajor radiusUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.magnetic_axis.z\nHeightUnits: m\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.vacuum_toroidal_field.b0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Units: T\nData Type: FLT_1D\nCoordinates: [\"waves.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: waves.vacuum_toroidal_field.r0\nReference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)Units: m\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].name\nName of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.library[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.name\nName of software generating IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.output_flag\nOutput flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used.Data Type: INT_1D\nCoordinates: [\"workflow.time\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.code.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.comment\nAny comment describing the content of this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.creation_date\nDate at which this data has been producedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.homogeneous_time\nThis node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.name\nUser-defined name for this IDS occurrenceData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence\nN/AData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.description\nVerbose descriptionData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.index\nInteger identifier (enumeration index within a list). Private identifier values must be indicated by a negative index.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.occurrence_type.name\nShort string identifierData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_get.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.infrastructure_put.version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].get_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].put_operation[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.plugins.node[:].readback[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provenance.node[:].path\nPath of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS.Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provenance.node[:].sources\nList of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the \"code\" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources.Data Type: STR_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.provider\nName of the person in charge of producing this dataData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.access_layer\nVersion of Access Layer used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.access_layer_language\nProgramming language of the Access Layer high level API used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.ids_properties.version_put.data_dictionary\nVersion of Data Dictionary used to PUT this IDSData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time\nGeneric timeUnits: s\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].commit\nUnique commit reference of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].description\nShort description of the software (type, purpose)Data Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].name\nName of software usedData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].parameters\nList of the code specific parameters in XML formatData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].repository\nURL of software repositoryData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.component[:].version\nUnique version (tag) of softwareData Type: STR_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.time_end\nTermination time for the workflow main time loopUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].control_float\nArray of real workflow control parameters used by this component (component specific)Units: mixed\nData Type: FLT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].control_integer\nArray of integer workflow control parameters used by this component (component specific)Data Type: INT_1D\nCoordinates: [\"1...N\"]","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].execution_mode\nComponent execution mode for current workflow cycle. 0 means the component is not executed and the workflow uses results from previous workflow cycle. 1 means the component is executed for this workflow cycle.Data Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].index\nIndex of the component in the ../../../component arrayData Type: INT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].time_interval_elapsed\nSimulation time interval for which this component has last computed its resultsUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].component[:].time_interval_request\nSimulation time interval for which this component is requested to compute its resultsUnits: s\nData Type: FLT_0D","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"dd_details.html","page":"-","title":"-","text":"note: workflow.time_loop.workflow_cycle[:].time\nTimeUnits: s\nData Type: FLT_0D","category":"page"},{"location":"deps.html#Ecosystem","page":"Ecosystem","title":"Ecosystem","text":"","category":"section"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"The FUSE project is built upon multiple Julia packages, many of which reside in the https://github.com/ProjectTorreyPines organization on GitHub.","category":"page"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"(Image: FUSE dependencies)","category":"page"},{"location":"deps.html","page":"Ecosystem","title":"Ecosystem","text":"ADAS [repo]\nBalanceOfPlantSurrogate [repo]\nCHEASE [repo]\nCoordinateConventions [repo]\nEPEDNN [repo]\nFiniteElementHermite [repo]\nFuseExchangeProtocol [repo]\nFuseUtils [repo]\nFusionMaterials [repo]\nIMAS [repo]\nIMASdd [repo]\nMXHEquilibrium [repo]\nMeshTools [repo]\nMillerExtendedHarmonic [repo]\nNEO [repo]\nNNeutronics [repo]\nQED [repo]\nRABBIT [repo]\nSimulationParameters [repo]\nTEQUILA [repo]\nTGLFNN [repo]\nTJLF [repo]\nThermalSystemModels [repo]\nVacuumFields [repo]","category":"page"},{"location":"install_saga.html#Getting-started-on-the-SAGA-cluster","page":"on SAGA","title":"Getting started on the SAGA cluster","text":"","category":"section"},{"location":"install_saga.html","page":"on SAGA","title":"on SAGA","text":"Get a SAGA account and ask to have a directory created for you under /mnt/beegfs/users/$USER\nInstall miniconda\ncd /mnt/beegfs/users/$USER\nwget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh\nsh Miniconda3-latest-Linux-x86_64.sh\nread and accept the license, and install under /mnt/beegfs/users/$USER/miniconda3, answer questions, and restart your shell\ninstall mamba for faster package management\nconda install -c conda-forge mamba\ninstall jupyterlab\nmamba install -c conda-forge jupyterlab\nSetup your environment to run CHEASE (optional)\nexport PATH=$PATH:/mnt/beegfs/users/meneghini/chease/src-f90\nCreate a symbolic link from /mnt/beegfs/users/$USER/julia/ to ~/.julia\nmkdir -p /mnt/beegfs/users/$USER/julia/dev\nln -s /mnt/beegfs/users/$USER/julia ~/.julia\n~/.julia is where the Julia will install itself by default, and this will trick it to install itself in the IR&D folder instead.\nFor convenience create also a symbolic link in your $HOME that points to the Julia dev folder:\nln -s /mnt/beegfs/users/$USER/julia/dev ~/julia_dev\nNow follow the standard Julia and FUSE installation instructions","category":"page"},{"location":"install_saga.html#Jupyter-on-SAGA-cluster","page":"on SAGA","title":"Jupyter on SAGA cluster","text":"","category":"section"},{"location":"install_saga.html","page":"on SAGA","title":"on SAGA","text":"Connect to saga and launch screen\nnote: Note\nYou can re-connect to an existing screen session with screen -r\nThen start the Jupyter lab server from the screen session (screen will keep jupyter running even when you log out)\njupyter lab --no-browser --port 55667\nCopy the token that you see on this session it should look something like token=1f1e0259cbc1..................\nOn your computer setup your ~/.ssh/config this way (need to do this only once):\nHost cybele cybele.gat.com\nHostname cybele.gat.com\nUser meneghini\nPort 2039\n\nHost sagae saga.gat.com\nHostname saga.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\nOn your computer start a tunnel going through cybele to saga\nssh -N -L localhost:33445:localhost:55667 sagae\nnote: Note\nKeep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.\nOn your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on saga. Use the token when prompted.","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.casename\nSort mnemonic name of the case being runType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.description\nLonger description of the case being runType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.init_from\nInitialize run fromType: Switch{Symbol}\nUnits: -\nOptions: ods, scalars","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.general.dd\ndd to initialize fromType: Entry{IMASdd.dd}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.time.pulse_shedule_time_basis\nTime basis used to discretize the pulse scheduleType: Entry{AbstractRange{Float64}}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.time.simulation_start\nTime at which the simulation startsType: Entry{Float64}\nUnits: s\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ods.filename\nODS.json file(s) from which equilibrium is loaded. Multiple comma-separated ODSs can be specified.Type: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.B0\nVacuum toroidal field at R0 [T]; Positive sign means anti-clockwise when viewing from above. The product R0B0 must be consistent with the btorvacuum_r field of the tf IDS.Type: Entry{Float64}\nUnits: T","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.R0\nGeometric genter of the plasma. NOTE: This also scales the radial build layers.Type: Entry{Float64}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.Z0\nZ offset of the machine midplaneType: Entry{Float64}\nUnits: m\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.ϵ\nPlasma inverse aspect ratio (a/R0). NOTE: This also scales the radial build layers.Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.κ\nPlasma elongation. NOTE: If < 1.0 it defines the fraction of maximum controllable elongation estimate.Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.tilt\nTilt of the plasma boundary [MXH c0]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.δ\nTriangularity of the plasma boundary [MXH sin(s1)]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.ζ\nSquareness of the plasma boundary [MXH -s2]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.𝚶\nOvality of the plasma boundary [MXH c1]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.twist\nTwist of the plasma boundary [MXH c2]Type: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.pressure_core\nOn axis pressureType: Entry{Float64}\nUnits: Pa","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.ip\nPlasma current (toroidal component). Positive sign means anti-clockwise when viewed from above.Type: Entry{Float64}\nUnits: A","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.xpoints\nX-points configurationType: Switch{Symbol}\nUnits: -\nOptions: lower, upper, double, none","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.ngrid\nResolution of the equilibrium gridType: Entry{Int64}\nUnits: -\nDefault: 129","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.equilibrium.field_null_surface\nψn value of the fieldnullsurface. Disable with 0.0Type: Entry{Float64}\nUnits: -\nDefault: 0.75","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.boundary_from\nThe starting r, z boundary taken fromType: Switch{Symbol}\nUnits: -\nOptions: scalars, MXH_params, rz_points, ods","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.MXH_params\nVector of MXH flatsType: Entry{Vector{Float64}}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.equilibrium.rz_points\nRZ boundary as Vector{Vector{Float64}}} : r = rzpoints[1], z = rz_points[2]Type: Entry{Vector{Vector{Float64}}}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.plasma_mode\nPlasma configurationType: Switch{Symbol}\nUnits: -\nOptions: H_mode, L_mode\nDefault: H_mode","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.w_ped\nPedestal width expressed in fraction of ψₙType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_value\nValue based on setup methodType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_setting\nWay to set the electron densityType: Switch{Symbol}\nUnits: -\nOptions: ne_ped, ne_line, greenwald_fraction, greenwald_fraction_ped","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ne_sep_to_ped_ratio\nRatio used to set the sepeartrix density based on the pedestal densityType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ne_core_to_ped_ratio\nRatio used to set the core density based on the pedestal densityType: Entry{Float64}\nUnits: -\nDefault: 1.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.ne_shaping\nDensity shaping factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.T_ratio\nTi/Te ratioType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.T_shaping\nTemperature shaping factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.Te_sep\nSeparatrix temperatureType: Entry{Float64}\nUnits: eV\nDefault: 80.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.zeff\nEffective ion chargeType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.rot_core\nDerivative of the flux surface averaged electrostatic potential with respect to the poloidal flux, multiplied by -1. This quantity is the toroidal angular rotation frequency due to the ExB drift, introduced in formula (43) of Hinton and Wong, Physics of Fluids 3082 (1985), also referred to as sonic flow in regimes in which the toroidal velocity is dominant over the poloidal velocityType: Entry{Float64}\nUnits: s^-1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ngrid\nResolution of the core_profiles gridType: Entry{Int64}\nUnits: -\nDefault: 101","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.bulk\nBulk ion speciesType: Entry{Symbol}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.impurity\nImpurity ion speciesType: Entry{Symbol}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.core_profiles.helium_fraction\nHelium density / electron density fractionType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.ejima\nEjima coefficientType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.core_profiles.polarized_fuel_fraction\nSpin polarized fuel fractionType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.n_coils_inside\nNumber of PF coils inside of the TFType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.n_coils_outside\nNumber of PF coils outside of the TFType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pf_active.technology\nPF coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.side\nSide of the vacuum vessel where the plasma is limited at breakdownType: Switch{Symbol}\nUnits: -\nOptions: hfs, lfs","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.ends_at\nUntil when does the rampup lastsType: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.rampup.diverted_at\nTime at which x-point is formed and plasma can peel-off the wallType: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.power_launched\nBeam powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.3","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.beam_energy\nBeam energyType: Entry{Float64}\nUnits: eV","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.beam_mass\nBeam massType: Entry{Float64}\nUnits: AU\nDefault: 2.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.nb_unit.1.toroidal_angle\nToroidal angle of injectionType: Entry{Float64}\nUnits: rad","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.efficiency_conversion\nConversion efficiency of electric power to neutral beam powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.nb_unit.1.efficiency_transmission\nTransmission efficiency of neutral beam from source to portType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ec_launcher.1.power_launched\nEC launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.5","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.025","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ec_launcher.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.frequency\nFrequency of pellets launchedType: Entry{Float64}\nUnits: Hz","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.5","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.25","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.pellet_launcher.1.shape\nThe pellet geometryType: Switch{Symbol}\nUnits: -\nOptions: spherical, cylindrical, rectangular\nDefault: spherical","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.species\nPellet speciesType: Switch{Symbol}\nUnits: -\nOptions: H, D, T, DT, C, Ne","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.pellet_launcher.1.size\nVector of geometric dimensions describing the pellet size for a given shape (spherical: [r], cylindrical: [d, l], rectangular: [x,y,z])Type: Entry{Vector{Float64}}\nUnits: m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.ic_antenna.1.power_launched\nIC launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.ic_antenna.1.efficiency_coupling\nCoupling efficiency of launched microwave power to the plasmaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.lh_antenna.1.power_launched\nLH launched powerType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.rho_0\nDesired radial location of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.8","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.width\nDesired width of the deposition profileType: Entry{Float64}\nUnits: -\nDefault: 0.05","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_conversion\nConversion efficiency of electric power to microwave powerType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_transmission\nTransmission efficiency of microwave power from generator to antennaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.lh_antenna.1.efficiency_coupling\nCoupling efficiency of launched microwave power to the plasmaType: Entry{Float64}\nUnits: -\nDefault: 1.0","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.hcd.power_scaling_cost_function\nEC, IC, LH, NB power optimization cost function, takes dd as input. Eg. dd -> (1.0 - IMAS.tauethermal(dd) / IMAS.taueh98(dd))Type: Entry{Function}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.name\nName of the layerType: Entry{String}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.thickness\nRelative thickness of the layer (layers actual thickness is scaled to match plasma R0)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.material\nMaterial of the layerType: Switch{Symbol}\nUnits: -\nOptions: tungsten, aluminum, graphite, nbti, flibe, water, plasma, lithium_lead, nb3sn_iter, nb3sn, vacuum, rebco, steel, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.shape\nShape of the layerType: Switch{IMAS.BuildLayerShape}\nUnits: -\nOptions: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.type\nType of the layerType: Switch{IMAS.BuildLayerType}\nUnits: -\nOptions: blanket, cryostat, gap, vessel, tf, oh, shield, port, wall, plasma, divertor","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.layers.1.side\nSide of the layerType: Switch{IMAS.BuildLayerSide}\nUnits: -\nOptions: hfs, in, lfs, out, lhfs","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.plasma_gap\nFraction of vacuum gap between first wall and plasma separatrix in radial buildType: Entry{Float64}\nUnits: -\nDefault: 0.1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.build.symmetric\nIs the build up-down symmetricType: Entry{Bool}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.divertors\nDivertors configurationType: Switch{Symbol}\nUnits: -\nOptions: lower, upper, double, none, from_x_points\nDefault: from_x_points","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.build.n_first_wall_conformal_layers\nNumber of layers that are conformal to the first wallType: Entry{Int64}\nUnits: -\nDefault: 1","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.bucked\nFlag for bucked boundary conditions between TF and OH (and center plug, if present)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.noslip\nFlag for no slip conditions between TF and OH (and center plug, if present)Type: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.center_stack.plug\nFlag for center plugType: Entry{Bool}\nUnits: -\nDefault: false","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.n_coils\nNumber of TF coilsType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.shape\nShape of the TF coilsType: Switch{IMAS.BuildLayerShape}\nUnits: -\nOptions: racetrack, princeton_D, mirror_double_ellipse, mirror_rectangle_ellipse, rectangle, circle_ellipse, triple_arc, convex_hull, silo, offset, mirror_princeton_D, undefined, rectangle_ellipse, mirror_circle_ellipse, double_ellipse, miller, mirror_princeton_D_scaled, mirror_princeton_D_exact, negative_offset, princeton_D_scaled, mirror_triple_arc","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.tf.ripple\nFraction of toroidal field ripple evaluated at the outermost radius of the plasma chamberType: Entry{Float64}\nUnits: -\nDefault: 0.01","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.tf.technology\nTF coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.oh.n_coils\nNumber of OH coilsType: Entry{Int64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.oh.technology\nOH coils technologyType: Switch{Symbol}\nUnits: -\nOptions: aluminum, nbti, nb3sn_iter, nb3sn, rebco, nb3sn_kdemo, copper","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.bop.cycle_type\nThermal cycle typeType: Switch{Symbol}\nUnits: -\nOptions: rankine, brayton\nDefault: rankine","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.power_electric_net\nNet electric power generated by the fusion power plantType: Entry{Float64}\nUnits: W","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.flattop_duration\nDuration of the flattop (use Inf for steady-state)Type: Entry{Float64}\nUnits: s","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.log10_flattop_duration\nLog10 value of the duration of the flattop (use Inf for steady-state). Preferred over flattop_duration for optimization studies.Type: Entry{Float64}\nUnits: log10(s)","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.tritium_breeding_ratio\nTritium breeding ratio of the whole plantType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.cost\nTotal FPP costType: Entry{Float64}\nUnits: $M","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.ne_peaking\nOn-axis electron density / volume-averaged electron denstiyType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.q_pol_omp\nPoloidal heat flux at the outer midplaneType: Entry{Float64}\nUnits: W/m^2","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.lh_power_threshold_fraction\nFraction of the LH power thresholdType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.h98y2\nH98y2 ITER elmy H-mode confinement scaling factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.hds03\nPetty 2003 H-mode thermal energy confinement scaling factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.beta_normal\nNormalized total plasma beta (MHD)Type: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.Psol_R\nPsol / RType: Entry{Float64}\nUnits: W/m","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"note: ini.requirements.q95\nEdge safety factorType: Entry{Float64}\nUnits: -","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.requirements.coil_j_margin\nMagnet coil Jcrit / JmaxType: Entry{Float64}\nUnits: -\nDefault: 0.4","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"
    ","category":"page"},{"location":"ini_details.html","page":"-","title":"-","text":"tip: ini.requirements.coil_stress_margin\nMagnet coil yieldstress / maxstressType: Entry{Float64}\nUnits: -\nDefault: 0.2","category":"page"},{"location":"license.html","page":"License","title":"License","text":" Apache License\n Version 2.0, January 2004\n http://www.apache.org/licenses/","category":"page"},{"location":"license.html","page":"License","title":"License","text":"TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Definitions.\n\"License\" shall mean the terms and conditions for use, reproduction, and distribution as defined by Sections 1 through 9 of this document.\n\"Licensor\" shall mean the copyright owner or entity authorized by the copyright owner that is granting the License.\n\"Legal Entity\" shall mean the union of the acting entity and all other entities that control, are controlled by, or are under common control with that entity. For the purposes of this definition, \"control\" means (i) the power, direct or indirect, to cause the direction or management of such entity, whether by contract or otherwise, or (ii) ownership of fifty percent (50%) or more of the outstanding shares, or (iii) beneficial ownership of such entity.\n\"You\" (or \"Your\") shall mean an individual or Legal Entity exercising permissions granted by this License.\n\"Source\" form shall mean the preferred form for making modifications, including but not limited to software source code, documentation source, and configuration files.\n\"Object\" form shall mean any form resulting from mechanical transformation or translation of a Source form, including but not limited to compiled object code, generated documentation, and conversions to other media types.\n\"Work\" shall mean the work of authorship, whether in Source or Object form, made available under the License, as indicated by a copyright notice that is included in or attached to the work (an example is provided in the Appendix below).\n\"Derivative Works\" shall mean any work, whether in Source or Object form, that is based on (or derived from) the Work and for which the editorial revisions, annotations, elaborations, or other modifications represent, as a whole, an original work of authorship. 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You are solely responsible for determining the appropriateness of using or redistributing the Work and assume any risks associated with Your exercise of permissions under this License.\nLimitation of Liability. In no event and under no legal theory, whether in tort (including negligence), contract, or otherwise, unless required by applicable law (such as deliberate and grossly negligent acts) or agreed to in writing, shall any Contributor be liable to You for damages, including any direct, indirect, special, incidental, or consequential damages of any character arising as a result of this License or out of the use or inability to use the Work (including but not limited to damages for loss of goodwill, work stoppage, computer failure or malfunction, or any and all other commercial damages or losses), even if such Contributor has been advised of the possibility of such damages.\nAccepting Warranty or Additional Liability. While redistributing the Work or Derivative Works thereof, You may choose to offer, and charge a fee for, acceptance of support, warranty, indemnity, or other liability obligations and/or rights consistent with this License. However, in accepting such obligations, You may act only on Your own behalf and on Your sole responsibility, not on behalf of any other Contributor, and only if You agree to indemnify, defend, and hold each Contributor harmless for any liability incurred by, or claims asserted against, such Contributor by reason of your accepting any such warranty or additional liability.","category":"page"},{"location":"license.html","page":"License","title":"License","text":"END OF TERMS AND CONDITIONS","category":"page"},{"location":"license.html","page":"License","title":"License","text":"APPENDIX: How to apply the Apache License to your work.","category":"page"},{"location":"license.html","page":"License","title":"License","text":" To apply the Apache License to your work, attach the following\n boilerplate notice, with the fields enclosed by brackets \"[]\"\n replaced with your own identifying information. (Don't include\n the brackets!) The text should be enclosed in the appropriate\n comment syntax for the file format. We also recommend that a\n file or class name and description of purpose be included on the\n same \"printed page\" as the copyright notice for easier\n identification within third-party archives.","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Copyright 2024 General Atomics","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Licensed under the Apache License, Version 2.0 (the \"License\"); you may not use this file except in compliance with the License. You may obtain a copy of the License at","category":"page"},{"location":"license.html","page":"License","title":"License","text":" http://www.apache.org/licenses/LICENSE-2.0","category":"page"},{"location":"license.html","page":"License","title":"License","text":"Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an \"AS IS\" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.","category":"page"},{"location":"pubs.html#Publications","page":"Publications","title":"Publications","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"📜 ArXiv preprint publication","category":"page"},{"location":"pubs.html#Taks/Posters","page":"Publications","title":"Taks/Posters","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Overview presentation","category":"page"},{"location":"pubs.html#APS-DPP-2024","page":"Publications","title":"APS DPP 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: digital twin for tokamak fusion power plant design and operations\n📊 Lyons Magnetohydrodynamics and electromagnetics in the FUSE integrated-modeling framework\n📊 Ghiozzi Risk minimization as a novel optimization objective in FUSE\n📊 Dose Predictions of heat and neutron loads onto FPP first walls in FUSE\n🎤 Slendebroek Optimizing fusion power plant designs for +/- triangularity through FUSE simulations","category":"page"},{"location":"pubs.html#IMEG-2024","page":"Publications","title":"IMEG 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini The FUSE framework and related IMAS activities","category":"page"},{"location":"pubs.html#Juliacon-2024","page":"Publications","title":"Juliacon 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Slendebroek The FUSE framework and its use for fusion power plant design optimization","category":"page"},{"location":"pubs.html#Sherwood-2024","page":"Publications","title":"Sherwood 2024","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: digital twin for tokamak fusion power plant design and operations","category":"page"},{"location":"pubs.html#IMEG-2023","page":"Publications","title":"IMEG 2023","text":"","category":"section"},{"location":"pubs.html","page":"Publications","title":"Publications","text":"🎤 Meneghini FUSE: A Modern Framework for Integrated Fusion Simulations","category":"page"},{"location":"examples.html#Worked-examples","page":"Examples","title":"Worked examples","text":"","category":"section"},{"location":"examples.html","page":"Examples","title":"Examples","text":"FUSE Jupyter examples are available and can be cloned to the current working directory with:","category":"page"},{"location":"examples.html","page":"Examples","title":"Examples","text":"fusebot install_examples","category":"page"},{"location":"examples.html","page":"Examples","title":"Examples","text":"To see/run those .ipynb files, you'll need to use Jupyter-Lab or VScode.","category":"page"},{"location":"install_omega.html#Getting-started-on-the-OMEGA-cluster","page":"on OMEGA","title":"Getting started on the OMEGA cluster","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Install miniconda\ncd # in your home folder\nwget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh\nsh Miniconda3-latest-Linux-x86_64.sh\nread and accept the license, and install under $HOME/miniconda3, answer questions, and restart your shell\ninstall mamba for faster package management\n$HOME/miniconda3/bin/conda install -c conda-forge mamba\nnote: Note\nWe use the full conda path to avoid picking up the system conda install. There is no system-wide mamba executable, so that's not necessary when running mamba.\ninstall jupyterlab\nmamba install -c conda-forge jupyterlab\nRemove module load defaults from your ~/.bashrc This module is used to run experimental tools like review+, efit_veiwer, etc... but it does not play well with the Julia executable. (alternatively you'll have to module purge or module unload defaults)\nNow follow the standard Julia and FUSE installation instructions\nSetup a multi-threaded Jupyter Julia kernel that does not take the whole login node\nexport JULIA_NUM_THREADS=10\nfusebot install_IJulia\n\nexport JULIA_NUM_THREADS=40\nfusebot install_IJulia\nOMEGA login nodes are a shared resource. Each login node has 40 cores. This will setup a Jupyter Julia kernel with both 10 and 40 threads. Use 10 threads on login nodes and 40 threads on worker nodes.","category":"page"},{"location":"install_omega.html#Distributed.jl-on-OMEGA","page":"on OMEGA","title":"Distributed.jl on OMEGA","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"We have found issues when trying to run parallel jobs using Distributed.jl on OMEGA. The fix for this is simple: don't use the Main environment, rather activate a separate environment.","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"This can be easily by doing the following in the first cell of your Jupyter notebook:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"using Pkg\nPkg.activate(\"$HOME/julia_runs/my_run\") # this is key, to avoid using the Main FUSE environment\nPkg.add((\"Plots\", \"FUSE\"))","category":"page"},{"location":"install_omega.html#Three-ways-to-run-parallel-jobs","page":"on OMEGA","title":"Three ways to run parallel jobs","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Keep in mind that each worker node on OMEGA has 128 CPUs","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Screen + Jupyter on the login node, workers on the worker nodes\nOK when the master process will not be doing a lot of work, and we need multiple nodes\nHere we will use the FUSE.parallel_environment(\"omega\", ...) call.\nScreen on the login node, Jupyter and workers on one worker node\nOK when the master process will be doing a lot of work, and we don't need more than one node\nHere we will use the FUSE.parallel_environment(\"localhost\", ...) call.\nScreen on the login node, Jupyter on a worker node, workers on different worker nodes\nOK when the master process will be doing a lot of work, and we need multiple nodes\nThis is more complex, and finicky. Avoid if possible.\nHere we will use the FUSE.parallel_environment(\"omega\", ...) call.","category":"page"},{"location":"install_omega.html#FUSE-on-OMEGA-cluster","page":"on OMEGA","title":"FUSE on OMEGA cluster","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Connect to omega and launch screen\nnote: Note\nYou can re-connect to an existing screen session with screen -r\nIf (and only if) you want to run Jupyter on a worker node do as follows:\nsrun --partition=ga-ird --nodes=1 --time=4-00:00:00 --pty bash -l\nnote: Note\nUse the queue, time, CPU, and memory limits that make the most sense for your application see these instructions for help\nThen start the Jupyter lab server from the screen session (screen will keep jupyter running even when you log out)\njupyter lab --no-browser --port 55667\nCopy the token that you see on this session it should look something like token=1f1e0259cbc1..................\nOn your computer setup your ~/.ssh/config this way (need to do this only once):\nHost cybele cybele.gat.com\nHostname cybele.gat.com\nUser meneghini\nPort 2039\n\nHost omegae omega.gat.com\nHostname omega.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\n\n# change XX to the worker node number you've been assigned to\nHost omegaXX omegaXX.gat.com\nHostname omegaXX.gat.com\nUser meneghini\nProxyCommand ssh -q cybele nc %h %p\nOn your computer start a tunnel going through cybele to omega\nssh -N -L localhost:33445:localhost:55667 omegae\nnote: Note\nKeep this terminal always open. You may need to re-issue this command whenever you put your laptop to sleep.\nOn your computer open a web browser tab to localhost:33445 to connect to the Jupyter-lab session on omega. Use the token when prompted.","category":"page"},{"location":"install_omega.html#Using-Revise-on-OMEGA","page":"on OMEGA","title":"Using Revise on OMEGA","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"When working on omega it seems ones need to manually trigger revise to pick up code changes:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"import Revise\nRevise.revise() # manual trigger","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"This is even if setting JULIA_REVISE_POLL=1","category":"page"},{"location":"install_omega.html#Using-GACODE-on-OMEGA-with-Julia","page":"on OMEGA","title":"Using GACODE on OMEGA with Julia","text":"","category":"section"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"Julia may be incompatible with some environments and will crash when launched. This is the case for the GACODE environment on OMEGA. To be able to run both GACODE and Julia on OMEGA (eg. to run NEO and TGLF) do the following:","category":"page"},{"location":"install_omega.html","page":"on OMEGA","title":"on OMEGA","text":"module load atom\nmodule unload gcc\nmodule unload env","category":"page"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"CurrentModule = IMAS","category":"page"},{"location":"dd.html#IMAS-data-structure","page":"Data Structure","title":"IMAS data structure","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"FUSE data is organized into hierarchical Interface Data Structures (IDSs), according to the ITER IMAS ontology. In addition to the usual IMAS IDSs (which we include on a need-by-need basis) FUSE also defines some of its own IDSs, to hold data that does not (yet?) fit into IMAS. Notable examples are the build, solid_mechanics, balance_of_plant, and costing IDSs.","category":"page"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"dd = IMAS.dd() (which stands for \"data dictionary\") is the root of the FUSE data structure","category":"page"},{"location":"dd.html#amns-data","page":"Data Structure","title":"amns data","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.amns_data{Float64} # hide","category":"page"},{"location":"dd.html#b-field-non-axisymmetric","page":"Data Structure","title":"b field non axisymmetric","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.b_field_non_axisymmetric{Float64} # hide","category":"page"},{"location":"dd.html#balance-of-plant","page":"Data Structure","title":"balance of plant","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.balance_of_plant{Float64} # hide","category":"page"},{"location":"dd.html#barometry","page":"Data Structure","title":"barometry","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.barometry{Float64} # hide","category":"page"},{"location":"dd.html#blanket","page":"Data Structure","title":"blanket","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.blanket{Float64} # hide","category":"page"},{"location":"dd.html#bolometer","page":"Data Structure","title":"bolometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.bolometer{Float64} # hide","category":"page"},{"location":"dd.html#bremsstrahlung-visible","page":"Data Structure","title":"bremsstrahlung visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.bremsstrahlung_visible{Float64} # hide","category":"page"},{"location":"dd.html#build","page":"Data Structure","title":"build","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.build{Float64} # hide","category":"page"},{"location":"dd.html#calorimetry","page":"Data Structure","title":"calorimetry","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.calorimetry{Float64} # hide","category":"page"},{"location":"dd.html#camera-ir","page":"Data Structure","title":"camera ir","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_ir{Float64} # hide","category":"page"},{"location":"dd.html#camera-visible","page":"Data Structure","title":"camera visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_visible{Float64} # hide","category":"page"},{"location":"dd.html#camera-x-rays","page":"Data Structure","title":"camera x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.camera_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#charge-exchange","page":"Data Structure","title":"charge exchange","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.charge_exchange{Float64} # hide","category":"page"},{"location":"dd.html#coils-non-axisymmetric","page":"Data Structure","title":"coils non axisymmetric","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.coils_non_axisymmetric{Float64} # hide","category":"page"},{"location":"dd.html#controllers","page":"Data Structure","title":"controllers","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.controllers{Float64} # hide","category":"page"},{"location":"dd.html#core-instant-changes","page":"Data Structure","title":"core instant changes","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_instant_changes{Float64} # hide","category":"page"},{"location":"dd.html#core-profiles","page":"Data Structure","title":"core profiles","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_profiles{Float64} # hide","category":"page"},{"location":"dd.html#core-sources","page":"Data Structure","title":"core sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_sources{Float64} # hide","category":"page"},{"location":"dd.html#core-transport","page":"Data Structure","title":"core transport","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.core_transport{Float64} # hide","category":"page"},{"location":"dd.html#costing","page":"Data Structure","title":"costing","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.costing{Float64} # hide","category":"page"},{"location":"dd.html#cryostat","page":"Data Structure","title":"cryostat","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.cryostat{Float64} # hide","category":"page"},{"location":"dd.html#dataset-description","page":"Data Structure","title":"dataset description","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.dataset_description{Float64} # hide","category":"page"},{"location":"dd.html#dataset-fair","page":"Data Structure","title":"dataset fair","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.dataset_fair{Float64} # hide","category":"page"},{"location":"dd.html#disruption","page":"Data Structure","title":"disruption","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.disruption{Float64} # hide","category":"page"},{"location":"dd.html#distribution-sources","page":"Data Structure","title":"distribution sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.distribution_sources{Float64} # hide","category":"page"},{"location":"dd.html#distributions","page":"Data Structure","title":"distributions","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.distributions{Float64} # hide","category":"page"},{"location":"dd.html#divertors","page":"Data Structure","title":"divertors","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.divertors{Float64} # hide","category":"page"},{"location":"dd.html#ec-launchers","page":"Data Structure","title":"ec launchers","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ec_launchers{Float64} # hide","category":"page"},{"location":"dd.html#ece","page":"Data Structure","title":"ece","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ece{Float64} # hide","category":"page"},{"location":"dd.html#edge-profiles","page":"Data Structure","title":"edge profiles","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_profiles{Float64} # hide","category":"page"},{"location":"dd.html#edge-sources","page":"Data Structure","title":"edge sources","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_sources{Float64} # hide","category":"page"},{"location":"dd.html#edge-transport","page":"Data Structure","title":"edge transport","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.edge_transport{Float64} # hide","category":"page"},{"location":"dd.html#em-coupling","page":"Data Structure","title":"em coupling","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.em_coupling{Float64} # hide","category":"page"},{"location":"dd.html#equilibrium","page":"Data Structure","title":"equilibrium","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.equilibrium{Float64} # hide","category":"page"},{"location":"dd.html#ferritic","page":"Data Structure","title":"ferritic","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ferritic{Float64} # hide","category":"page"},{"location":"dd.html#focs","page":"Data Structure","title":"focs","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.focs{Float64} # hide","category":"page"},{"location":"dd.html#gas-injection","page":"Data Structure","title":"gas injection","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gas_injection{Float64} # hide","category":"page"},{"location":"dd.html#gas-pumping","page":"Data Structure","title":"gas pumping","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gas_pumping{Float64} # hide","category":"page"},{"location":"dd.html#gyrokinetics-local","page":"Data Structure","title":"gyrokinetics local","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.gyrokinetics_local{Float64} # hide","category":"page"},{"location":"dd.html#hard-x-rays","page":"Data Structure","title":"hard x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.hard_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#ic-antennas","page":"Data Structure","title":"ic antennas","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ic_antennas{Float64} # hide","category":"page"},{"location":"dd.html#interferometer","page":"Data Structure","title":"interferometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.interferometer{Float64} # hide","category":"page"},{"location":"dd.html#iron-core","page":"Data Structure","title":"iron core","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.iron_core{Float64} # hide","category":"page"},{"location":"dd.html#langmuir-probes","page":"Data Structure","title":"langmuir probes","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.langmuir_probes{Float64} # hide","category":"page"},{"location":"dd.html#lh-antennas","page":"Data Structure","title":"lh antennas","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.lh_antennas{Float64} # hide","category":"page"},{"location":"dd.html#magnetics","page":"Data Structure","title":"magnetics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.magnetics{Float64} # hide","category":"page"},{"location":"dd.html#mhd","page":"Data Structure","title":"mhd","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mhd{Float64} # hide","category":"page"},{"location":"dd.html#mhd-linear","page":"Data Structure","title":"mhd linear","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mhd_linear{Float64} # hide","category":"page"},{"location":"dd.html#mse","page":"Data Structure","title":"mse","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.mse{Float64} # hide","category":"page"},{"location":"dd.html#nbi","page":"Data Structure","title":"nbi","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.nbi{Float64} # hide","category":"page"},{"location":"dd.html#neutron-diagnostic","page":"Data Structure","title":"neutron diagnostic","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.neutron_diagnostic{Float64} # hide","category":"page"},{"location":"dd.html#neutronics","page":"Data Structure","title":"neutronics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.neutronics{Float64} # hide","category":"page"},{"location":"dd.html#ntms","page":"Data Structure","title":"ntms","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.ntms{Float64} # hide","category":"page"},{"location":"dd.html#operational-instrumentation","page":"Data Structure","title":"operational instrumentation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.operational_instrumentation{Float64} # hide","category":"page"},{"location":"dd.html#pellets","page":"Data Structure","title":"pellets","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pellets{Float64} # hide","category":"page"},{"location":"dd.html#pf-active","page":"Data Structure","title":"pf active","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_active{Float64} # hide","category":"page"},{"location":"dd.html#pf-passive","page":"Data Structure","title":"pf passive","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_passive{Float64} # hide","category":"page"},{"location":"dd.html#pf-plasma","page":"Data Structure","title":"pf plasma","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pf_plasma{Float64} # hide","category":"page"},{"location":"dd.html#plasma-initiation","page":"Data Structure","title":"plasma initiation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.plasma_initiation{Float64} # hide","category":"page"},{"location":"dd.html#polarimeter","page":"Data Structure","title":"polarimeter","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.polarimeter{Float64} # hide","category":"page"},{"location":"dd.html#pulse-schedule","page":"Data Structure","title":"pulse schedule","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.pulse_schedule{Float64} # hide","category":"page"},{"location":"dd.html#radiation","page":"Data Structure","title":"radiation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.radiation{Float64} # hide","category":"page"},{"location":"dd.html#real-time-data","page":"Data Structure","title":"real time data","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.real_time_data{Float64} # hide","category":"page"},{"location":"dd.html#reflectometer-fluctuation","page":"Data Structure","title":"reflectometer fluctuation","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.reflectometer_fluctuation{Float64} # hide","category":"page"},{"location":"dd.html#reflectometer-profile","page":"Data Structure","title":"reflectometer profile","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.reflectometer_profile{Float64} # hide","category":"page"},{"location":"dd.html#refractometer","page":"Data Structure","title":"refractometer","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.refractometer{Float64} # hide","category":"page"},{"location":"dd.html#requirements","page":"Data Structure","title":"requirements","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.requirements{Float64} # hide","category":"page"},{"location":"dd.html#runaway-electrons","page":"Data Structure","title":"runaway electrons","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.runaway_electrons{Float64} # hide","category":"page"},{"location":"dd.html#sawteeth","page":"Data Structure","title":"sawteeth","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.sawteeth{Float64} # hide","category":"page"},{"location":"dd.html#soft-x-rays","page":"Data Structure","title":"soft x rays","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.soft_x_rays{Float64} # hide","category":"page"},{"location":"dd.html#solid-mechanics","page":"Data Structure","title":"solid mechanics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.solid_mechanics{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-mass","page":"Data Structure","title":"spectrometer mass","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_mass{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-uv","page":"Data Structure","title":"spectrometer uv","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_uv{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-visible","page":"Data Structure","title":"spectrometer visible","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_visible{Float64} # hide","category":"page"},{"location":"dd.html#spectrometer-x-ray-crystal","page":"Data Structure","title":"spectrometer x ray crystal","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spectrometer_x_ray_crystal{Float64} # hide","category":"page"},{"location":"dd.html#spi","page":"Data Structure","title":"spi","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.spi{Float64} # hide","category":"page"},{"location":"dd.html#stability","page":"Data Structure","title":"stability","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.stability{Float64} # hide","category":"page"},{"location":"dd.html#summary","page":"Data Structure","title":"summary","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.summary{Float64} # hide","category":"page"},{"location":"dd.html#temporary","page":"Data Structure","title":"temporary","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.temporary{Float64} # hide","category":"page"},{"location":"dd.html#tf","page":"Data Structure","title":"tf","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.tf{Float64} # hide","category":"page"},{"location":"dd.html#thomson-scattering","page":"Data Structure","title":"thomson scattering","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.thomson_scattering{Float64} # hide","category":"page"},{"location":"dd.html#transport-solver-numerics","page":"Data Structure","title":"transport solver numerics","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.transport_solver_numerics{Float64} # hide","category":"page"},{"location":"dd.html#turbulence","page":"Data Structure","title":"turbulence","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.turbulence{Float64} # hide","category":"page"},{"location":"dd.html#wall","page":"Data Structure","title":"wall","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.wall{Float64} # hide","category":"page"},{"location":"dd.html#waves","page":"Data Structure","title":"waves","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.waves{Float64} # hide","category":"page"},{"location":"dd.html#workflow","page":"Data Structure","title":"workflow","text":"","category":"section"},{"location":"dd.html","page":"Data Structure","title":"Data Structure","text":"using IMASdd # hide\nIMASdd.workflow{Float64} # hide","category":"page"},{"location":"index.html#FUSE.jl","page":"Main","title":"FUSE.jl","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE (FUsion Synthesis Engine) is an open-source framework for the integrated design of Fusion Power Plants (FPP). Originally developed by General Atomics, FUSE is now publicly available under the Apache 2.0 license.","category":"page"},{"location":"index.html#Upcoming-2024-Code-Camp","page":"Main","title":"📢 Upcoming 2024 Code Camp 📢","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Join the FUSE community and help shape the future of Fusion Power Plant design:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Date: Dec 9th - 13th\nLocation: In person @ General Atomics\nSeats: Limited to 40 participants - 🔥 REGISTER TODAY!","category":"page"},{"location":"index.html#Resources","page":"Main","title":"Resources","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Here are some key resources for getting started with FUSE:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"📚 Online documentation\n📜 Preprint publication\n🆘 Discord community\n🗒️ Weekly devs meeting minutes","category":"page"},{"location":"index.html#Objectives","page":"Main","title":"Objectives","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE aims to achieve the following objectives:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"⚡ Provide a highly efficient, modular framework that tightly couples models across different domains.\n🧩 Integrate plasma physics, engineering, control, balance of plant, and costing systems.\n🤖 Leverage machine learning to overcome the typical fidelity/speed tradeoff in simulations.\n⏱️ Support both stationary and time-dependent simulations.\n💻 Harness parallelism and high-performance computing (HPC) for large-scale studies.\n🎯 Perform multi-objective constrained optimization to explore design tradeoffs.\n🔍 Enable comprehensive sensitivity analysis and uncertainty quantification.","category":"page"},{"location":"index.html#Basic-Concepts","page":"Main","title":"Basic Concepts","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE is entirely written in Julia and is structured around the following core concepts:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"📂 Data storage: All data is stored in the dd structure, which follows the ITER IMAS ontology.\n🧠 Actors: The core components of FUSE simulations are physics and engineering actors.\n🕹️ Control: Actor functionality is governed by act parameters.\n🚀 Initialization: The data structure can be initialized from 0D ini parameters.\n🔧 Use cases: FUSE includes templates for various machines (e.g., FPP, ITER, ARC).\n🔄 Workflows: Self-contained studies and optimizations are conducted via workflows, typically involving multiple FUSE simulations.\n🌍 Interoperability: FUSE interfaces with existing modeling tools like OMFIT/OMAS and the IMAS ecosystem.","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"A diagram illustrating these concepts is provided below: (Image: FUSE Diagram)","category":"page"},{"location":"index.html#Usage-Example","page":"Main","title":"Usage Example","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Here’s a simple example of setting up and running a FUSE simulation in Julia:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"using FUSE\n\n# Obtain `ini` and `act` parameters for a specific use case\nini, act = FUSE.case_parameters(:FPP)\n\n# Initialize the `dd` structure with 0D parameters\ndd = FUSE.init(ini, act)\n\n# Run a stationary plasma actor simulation\nFUSE.ActorStationaryPlasma(dd, act)\n\n# Get an overview of the simulation results\nFUSE.digest(dd)","category":"page"},{"location":"index.html#Installation","page":"Main","title":"Installation","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"FUSE and its related packages are available through the FuseRegistry. To install:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Install Julia\nAdd the FuseRegistry and General registries, then install FUSE:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"using Pkg\nPkg.Registry.add(RegistrySpec(url=\"https://github.com/ProjectTorreyPines/FuseRegistry.jl.git\"))\nPkg.Registry.add(\"General\")\nPkg.add(\"FUSE\")","category":"page"},{"location":"index.html#Citation","page":"Main","title":"Citation","text":"","category":"section"},{"location":"index.html","page":"Main","title":"Main","text":"Please cite this work as follows:","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"@article{meneghini2024fuse,\nauthor = {Meneghini, O. and Slendebroek, T. and Lyons, B.C. and McLaughlin, K. and McClenaghan, J. and Stagner, L. and Harvey, J. and Neiser, T.F. and Ghiozzi, A. and Dose, G. and Guterl, J. and Zalzali, A. and Cote, T. and Shi, N. and Weisberg, D. and Smith, S.P. and Grierson, B.A. and Candy, J.},\ndoi = {10.48550/arXiv.2409.05894},\njournal = {arXiv},\ntitle = {{FUSE (Fusion Synthesis Engine): A Next Generation Framework for Integrated Design of Fusion Pilot Plants}},\nyear = {2024}\n}","category":"page"},{"location":"index.html","page":"Main","title":"Main","text":"Last update on 2024-10-22T02:41:39.598","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"EditURL = \"tutorial.jl\"","category":"page"},{"location":"tutorial.html#FUSE-Introductory-Tutorial","page":"Tutorial","title":"FUSE Introductory Tutorial","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Download this tutorial from the FuseExamples repository","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Import the necessary packages","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"using Plots # for plotting\nusing FUSE # this will also import IMAS in the current namespace","category":"page"},{"location":"tutorial.html#Starting-from-a-use-case","page":"Tutorial","title":"Starting from a use-case","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE comes with some predefined use-cases, some of which are used for regression testing. Note that some use cases are for non-nuclear experiments and certain Actors like Blankets or BalanceOfPlant will not perform any actions.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.test_cases","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Get initial parameters (ini) and actions (act) for a given use-case","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ini, act = FUSE.case_parameters(:KDEMO);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Modifying ini parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ini.equilibrium.B0 = 7.8\nini.equilibrium.R0 = 6.5;\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Modifying act parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"act.ActorCoreTransport.model = :FluxMatcher;\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Initialize the data dictionary (dd) using the 0D parameters.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"NOTE: init() does not return a self-consistent solution, just a plausible starting point to initialize our simulations!","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd = FUSE.init(ini, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Using checkpoints to save and restore states (we'll use this later)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"chk = FUSE.Checkpoint()\n@checkin chk :init dd ini act","category":"page"},{"location":"tutorial.html#Exploring-the-data-dictionary","page":"Tutorial","title":"Exploring the data dictionary","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE stores data following the IMAS data schema.\nThe root of the data structure is dd, which stands for \"Data Dictionary\".\nMore details are available in the documentation.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Display part of the equilibrium data in dd","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.time_slice[2].boundary","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"this can be done up to a certain depth with print_tree","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(dd.equilibrium.time_slice[2].boundary; maxdepth=1)","category":"page"},{"location":"tutorial.html#Plotting-data-from-dd","page":"Tutorial","title":"Plotting data from dd","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE provides Plots.jl recipes for visualizing data from dd, this means different plots are shown by calling the same plot() function on different items in the data structure. Learn more about Plots.jl here","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"For example plotting the equilibrium...","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.equilibrium)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"...or the core profiles","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Whant to know what arguments can be passed? use help_plot() function","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"help_plot(dd.equilibrium; core_profiles_overlay=true, psi_levels_in=21, psi_levels_out=5, show_secondary_separatrix=true, coordinate=:psi_norm)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"These plots can be composed by calling plot!() instead of plot()","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.equilibrium; color=:gray, cx=true)\nplot!(dd.build; equilibrium=false, pf_active=false)\nplot!(dd.pf_active)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Plotting an array...","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1].pressure_thermal)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"...is different from plotting a field from the IDS (which plots the quantity against its coordinate and with units)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1], :pressure_thermal)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Customizing plot attributes:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_profiles.profiles_1d[1], :pressure_thermal; label=\"\", linewidth=2, color=:red, labelfontsize=25)","category":"page"},{"location":"tutorial.html#Working-with-time-series","page":"Tutorial","title":"Working with time series","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The IMAS data structure supports time-dependent data, and IMAS.jl provides ways to handle time data efficiently.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Each dd has a global_time attribute, and actors operate at such time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Here we see that equilibrium has mulitiple time_slices","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Accessing time-dependent arrays of structures, via integer index","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[2]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"At a given time, by passing the time as a floating point number (in seconds)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[0.0]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"At the global time, leaving the square brackets empty","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"eqt = dd.equilibrium.time_slice[]\neqt.time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Using the @ddtime macro to access and modify time-dependent arrays at dd.global_time:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.equilibrium.vacuum_toroidal_field.b0","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Accessing data at dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"my_b0 = @ddtime(dd.equilibrium.vacuum_toroidal_field.b0)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Writin data at dd.global_time","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@ddtime(dd.equilibrium.vacuum_toroidal_field.b0 = my_b0 + 1)\n\ndd.equilibrium.vacuum_toroidal_field.b0","category":"page"},{"location":"tutorial.html#Expressions-in-dd","page":"Tutorial","title":"Expressions in dd","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Some fields in the data dictionary are expressions (ie. Functions). For example dd.core_profiles.profiles_1d[].pressure is dynamically calculated as the product of thermal densities and temperature with addition of fast ions contributions","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(dd.core_profiles.profiles_1d[1]; maxdepth=1)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"accessing a dynamic expression, automatically evaluates it (in the pressure example, we get an array with data)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.core_profiles.profiles_1d[1].electrons.pressure","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"In addition to evaluating expressions by accessing them, expressions in the tree can be evaluated using IMAS.freeze()","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"print_tree(IMAS.freeze(dd.core_profiles.profiles_1d[1]); maxdepth=1)","category":"page"},{"location":"tutorial.html#Whole-facility-design","page":"Tutorial","title":"Whole facility design","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Here we restore the :init checkpoint that we had previously stored. Resetting any changes to dd, ini, and act that we did in the meantime.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkout chk :init dd ini act","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Actors in FUSE can be executed by passing two arguments to them: dd and act. Internally, actors can call other actors, creating workflows. For example, the ActorWholeFacility can be used to to get a self-consistent stationary whole facility design. The actors: print statements with their nested output tell us what actors are calling other actors.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorWholeFacility(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Like before we can checkpoint results for later use","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkin chk :awf dd ini act","category":"page"},{"location":"tutorial.html#Running-a-custom-workflow","page":"Tutorial","title":"Running a custom workflow","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's now run a series of actors similar to what ActorWholeFacility does and play around with plotting to get a sense of what each individual actor does.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's start again from after the initialization stage","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkout chk :init dd ini act","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's start by positioning the PF coils, so that we stand a chance to reproduce the desired plasma shape. This will be important to ensure the stability of the ActorStationaryPlasma that we are going to run next.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorPFdesign(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorStationaryPlasma iterates between plasma transport, pedestal, equilibrium and sources to return a self-consistent plasma solution","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"peq = plot(dd.equilibrium; label=\"before\")\npcp = plot(dd.core_profiles; color=:gray, label=\"before\")\nFUSE.ActorStationaryPlasma(dd, act);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"we can compare equilibrium before and after the self-consistency loop","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot!(peq, dd.equilibrium; label=\"after\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"we can compare core_profiles before and after the self-consistency loop","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot!(pcp, dd.core_profiles; label=\"after\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"here are the sources","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_sources)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"and the flux-matched transport","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.core_transport)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"HFS sizing actor changes the thickness of the OH and TF layers on the high field side to satisfy current and stresses constraints","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.build)\nFUSE.ActorHFSsizing(dd, act);\nplot!(dd.build; cx=false)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The stresses on the center stack are stored in the solid_mechanics IDS","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.solid_mechanics.center_stack.stress)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"LFS sizing actors change location of the outer TF leg to meet ripple requirements","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"plot(dd.build)\nFUSE.ActorLFSsizing(dd, act);\nplot!(dd.build; cx=false)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"A custom show() method is defined to print the summary of dd.build.layer","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd.build.layer","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorHFSsizing and ActorLFSsizing only change the layer's thicknesses, so we then need to trigger a build of the 2D cross-sections after them:","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorCXbuild(dd, act);\nplot(dd.build)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Generate passive structures information (for now the vacuum vessel)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorPassiveStructures(dd, act)\nplot(dd.pf_passive)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"We can now give the PF coils their final position given the new build","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorPFdesign(dd, act);\nplot(actor)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"With information about both pfactive and pfpassive we can now evaluate vertical stability","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorVerticalStability(dd, act)\nIMAS.freeze(dd.mhd_linear)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorNeutronics calculates the heat flux on the first wall","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorNeutronics(dd, act);\np = plot(; layout=2, size=(900, 350))\nplot!(p, dd.neutronics.time_slice[].wall_loading, subplot=1)\nplot!(p, FUSE.define_neutrons(dd, 100000)[1], dd.equilibrium.time_slice[]; subplot=1, colorbar_entry=false)\nplot!(p, dd.neutronics.time_slice[].wall_loading; cx=false, subplot=2, ylabel=\"\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorBlanket will change the thickess of the first wall, breeder, shield, and Li6 enrichment to achieve target TBR","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorBlanket(dd, act);\nprint_tree(IMAS.freeze(dd.blanket); maxdepth=5)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorDivertors actor calculates the divertors heat flux","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorDivertors(dd, act);\nprint_tree(IMAS.freeze(dd.divertors); maxdepth=4)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"The ActorBalanceOfPlant calculates the optimal cooling flow rates for the heat sources (breeder, divertor, and wall) and get an efficiency for the electricity conversion cycle","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"actor = FUSE.ActorBalanceOfPlant(dd, act);\nplot(actor)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"ActorCosting will break down the capital and operational costs","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.ActorCosting(dd, act)\nplot(dd.costing)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Let's checkpoint our results","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"@checkin chk :manual dd ini act","category":"page"},{"location":"tutorial.html#Saving-and-loading-data","page":"Tutorial","title":"Saving and loading data","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"tutorial_temp_dir = tempdir()\nfilename = joinpath(tutorial_temp_dir, \"$(ini.general.casename).json\")","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"When saving data to be shared outside of FUSE, one can set freeze=true so that all expressions in the dd are evaluated and saved to file.","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"IMAS.imas2json(dd, filename; freeze=false, strict=false);\nnothing #hide","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Load from JSON","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd1 = IMAS.json2imas(filename);\nnothing #hide","category":"page"},{"location":"tutorial.html#Comparing-two-IDSs","page":"Tutorial","title":"Comparing two IDSs","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"We can introduce a change in the dd1 and spot it with the diff function","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"dd1.equilibrium.time_slice[1].time = -100.0\nIMAS.diff(dd.equilibrium, dd1.equilibrium)","category":"page"},{"location":"tutorial.html#Summary","page":"Tutorial","title":"Summary","text":"","category":"section"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Snapshot of dd in 0D quantities (evaluated at dd.global_time)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"FUSE.extract(dd)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"Extract + plots saved to PDF (or printed to screen it filename is omitted)","category":"page"},{"location":"tutorial.html","page":"Tutorial","title":"Tutorial","text":"filename = joinpath(tutorial_temp_dir, \"$(ini.general.casename).pdf\")\nFUSE.digest(dd)#, filename)","category":"page"}] } diff --git a/dev/tutorial-024cc0d3.svg b/dev/tutorial-024cc0d3.svg new file mode 100644 index 000000000..c129c31f5 --- /dev/null +++ b/dev/tutorial-024cc0d3.svg @@ -0,0 +1,1921 @@ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + 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+ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + diff --git a/dev/tutorial-fc924334.svg b/dev/tutorial-b42e05ec.svg similarity index 84% rename from dev/tutorial-fc924334.svg rename to dev/tutorial-b42e05ec.svg index f619f8067..d893178d5 100644 --- a/dev/tutorial-fc924334.svg +++ b/dev/tutorial-b42e05ec.svg @@ -1,46 +1,46 @@ - + - + - + - + - + - - - - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + + + + + + + + + + + + + + + + + + diff --git a/dev/tutorial-be0cb2ab.svg b/dev/tutorial-be0cb2ab.svg deleted file mode 100644 index af099615e..000000000 --- a/dev/tutorial-be0cb2ab.svg +++ /dev/null @@ -1,279 +0,0 @@ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 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+++ b/dev/tutorial-c97d5ed4.svg @@ -0,0 +1,86 @@ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + diff --git a/dev/tutorial-026f2600.svg b/dev/tutorial-d59647df.svg similarity index 83% rename from dev/tutorial-026f2600.svg rename to dev/tutorial-d59647df.svg index 9fca8e9da..cd5928767 100644 --- a/dev/tutorial-026f2600.svg +++ b/dev/tutorial-d59647df.svg @@ -1,136 +1,136 @@ - + - + - + - + - + - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + - + - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + - + - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + diff --git a/dev/tutorial-f2697e03.svg 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    Plotting data from dd

    FUSE provides Plots.jl recipes for visualizing data from dd, this means different plots are shown by calling the same plot() function on different items in the data structure. Learn more about Plots.jl here

    For example plotting the equilibrium...

    plot(dd.equilibrium)
    Example block output

    ...or the core profiles

    plot(dd.core_profiles)
    Example block output

    Whant to know what arguments can be passed? use help_plot() function

    help_plot(dd.equilibrium; core_profiles_overlay=true, psi_levels_in=21, psi_levels_out=5, show_secondary_separatrix=true, coordinate=:psi_norm)
    Example block output

    These plots can be composed by calling plot!() instead of plot()

    plot(dd.equilibrium; color=:gray, cx=true)
+   ⋮

    Plotting data from dd

    FUSE provides Plots.jl recipes for visualizing data from dd, this means different plots are shown by calling the same plot() function on different items in the data structure. Learn more about Plots.jl here

    For example plotting the equilibrium...

    plot(dd.equilibrium)
    Example block output

    ...or the core profiles

    plot(dd.core_profiles)
    Example block output

    Whant to know what arguments can be passed? use help_plot() function

    help_plot(dd.equilibrium; core_profiles_overlay=true, psi_levels_in=21, psi_levels_out=5, show_secondary_separatrix=true, coordinate=:psi_norm)
    Example block output

    These plots can be composed by calling plot!() instead of plot()

    plot(dd.equilibrium; color=:gray, cx=true)
 plot!(dd.build; equilibrium=false, pf_active=false)
-plot!(dd.pf_active)
    Example block output

    Plotting an array...

    plot(dd.core_profiles.profiles_1d[1].pressure_thermal)
    Example block output

    ...is different from plotting a field from the IDS (which plots the quantity against its coordinate and with units)

    plot(dd.core_profiles.profiles_1d[1], :pressure_thermal)
    Example block output

    Customizing plot attributes:

    plot(dd.core_profiles.profiles_1d[1], :pressure_thermal; label="", linewidth=2, color=:red, labelfontsize=25)
    Example block output

    Working with time series

    The IMAS data structure supports time-dependent data, and IMAS.jl provides ways to handle time data efficiently.

    Each dd has a global_time attribute, and actors operate at such time

    dd.global_time
    0.0

    Here we see that equilibrium has mulitiple time_slices

    dd.equilibrium.time
    2-element Vector{Float64}:
+plot!(dd.pf_active)
    Example block output

    Plotting an array...

    plot(dd.core_profiles.profiles_1d[1].pressure_thermal)
    Example block output

    ...is different from plotting a field from the IDS (which plots the quantity against its coordinate and with units)

    plot(dd.core_profiles.profiles_1d[1], :pressure_thermal)
    Example block output

    Customizing plot attributes:

    plot(dd.core_profiles.profiles_1d[1], :pressure_thermal; label="", linewidth=2, color=:red, labelfontsize=25)
    Example block output

    Working with time series

    The IMAS data structure supports time-dependent data, and IMAS.jl provides ways to handle time data efficiently.

    Each dd has a global_time attribute, and actors operate at such time

    dd.global_time
    0.0

    Here we see that equilibrium has mulitiple time_slices

    dd.equilibrium.time
    2-element Vector{Float64}:
  -Inf
    0.0

    Accessing time-dependent arrays of structures, via integer index

    eqt = dd.equilibrium.time_slice[2]
 eqt.time
    0.0

    At a given time, by passing the time as a floating point number (in seconds)

    eqt = dd.equilibrium.time_slice[0.0]
@@ -189,14 +189,11 @@
 actors:    EPED
 actors:   CoreTransport
 actors:    FluxMatcher
-actors:     FluxCalculator
-actors:      TGLF
-actors:      Neoclassical
 actors:   Current
 actors:    QED
 actors:   Equilibrium
 actors:    TEQUILA
-actors:   --------------- 1/5 @ 630.02%
+actors:   --------------- 1/5 @ 647.61%
 actors:   HCD
 actors:    SimpleEC
 actors:    SimpleIC
@@ -213,7 +210,7 @@
 actors:    QED
 actors:   Equilibrium
 actors:    TEQUILA
-actors:   --------------- 2/5 @ 435.70%
+actors:   --------------- 2/5 @ 429.53%
 actors:   HCD
 actors:    SimpleEC
 actors:    SimpleIC
@@ -230,7 +227,7 @@
 actors:    QED
 actors:   Equilibrium
 actors:    TEQUILA
-actors:   --------------- 3/5 @ 137.11%
+actors:   --------------- 3/5 @ 225.97%
 actors:   HCD
 actors:    SimpleEC
 actors:    SimpleIC
@@ -247,7 +244,26 @@
 actors:    QED
 actors:   Equilibrium
 actors:    TEQUILA
-actors:   --------------- 4/5 @ 68.26%
+actors:   --------------- 4/5 @ 385.71%
+actors:   HCD
+actors:    SimpleEC
+actors:    SimpleIC
+actors:    SimpleLH
+actors:    SimpleNB
+actors:    SimplePellet
+actors:   Current
+actors:    QED
+actors:   Pedestal
+actors:    EPED
+actors:   CoreTransport
+actors:    FluxMatcher
+actors:   Current
+actors:    QED
+actors:   Equilibrium
+actors:    TEQUILA
+actors:   --------------- 5/5 @ 132.56%
+┌ Warning: Max number of iterations (5) has been reached with convergence error of [0.324, 0.215, 0.113, 0.193, 0.066] compared to threshold of 0.05
+└ @ FUSE ~/work/FUSE.jl/FUSE.jl/src/actors/compound/stationary_plasma_actor.jl:193
 actors:  StabilityLimits
 actors:  HFSsizing
 actors:   FluxSwing
@@ -281,14 +297,28 @@
 actors:   EPED
 actors:  CoreTransport
 actors:   FluxMatcher
-actors:    FluxCalculator
-actors:     TGLF
-actors:     Neoclassical
 actors:  Current
 actors:   QED
 actors:  Equilibrium
 actors:   TEQUILA
-actors:  --------------- 1/5 @ 630.02%
+actors:  --------------- 1/5 @ 647.61%
+actors:  HCD
+actors:   SimpleEC
+actors:   SimpleIC
+actors:   SimpleLH
+actors:   SimpleNB
+actors:   SimplePellet
+actors:  Current
+actors:   QED
+actors:  Pedestal
+actors:   EPED
+actors:  CoreTransport
+actors:   FluxMatcher
+actors:  Current
+actors:   QED
+actors:  Equilibrium
+actors:   TEQUILA
+actors:  --------------- 2/5 @ 429.53%
 actors:  HCD
 actors:   SimpleEC
 actors:   SimpleIC
@@ -305,7 +335,7 @@
 actors:   QED
 actors:  Equilibrium
 actors:   TEQUILA
-actors:  --------------- 2/5 @ 435.70%
+actors:  --------------- 3/5 @ 225.97%
 actors:  HCD
 actors:   SimpleEC
 actors:   SimpleIC
@@ -322,7 +352,7 @@
 actors:   QED
 actors:  Equilibrium
 actors:   TEQUILA
-actors:  --------------- 3/5 @ 137.11%
+actors:  --------------- 4/5 @ 385.71%
 actors:  HCD
 actors:   SimpleEC
 actors:   SimpleIC
@@ -339,17 +369,19 @@
 actors:   QED
 actors:  Equilibrium
 actors:   TEQUILA
-actors:  --------------- 4/5 @ 68.26%

    we can compare equilibrium before and after the self-consistency loop

    plot!(peq, dd.equilibrium; label="after")
    Example block output

    we can compare core_profiles before and after the self-consistency loop

    plot!(pcp, dd.core_profiles; label="after")
    Example block output

    here are the sources

    plot(dd.core_sources)
    Example block output

    and the flux-matched transport

    plot(dd.core_transport)
    Example block output

    HFS sizing actor changes the thickness of the OH and TF layers on the high field side to satisfy current and stresses constraints

    plot(dd.build)
+actors:  --------------- 5/5 @ 132.56%
+┌ Warning: Max number of iterations (5) has been reached with convergence error of [0.324, 0.215, 0.113, 0.193, 0.066] compared to threshold of 0.05
+└ @ FUSE ~/work/FUSE.jl/FUSE.jl/src/actors/compound/stationary_plasma_actor.jl:193

    we can compare equilibrium before and after the self-consistency loop

    plot!(peq, dd.equilibrium; label="after")
    Example block output

    we can compare core_profiles before and after the self-consistency loop

    plot!(pcp, dd.core_profiles; label="after")
    Example block output

    here are the sources

    plot(dd.core_sources)
    Example block output

    and the flux-matched transport

    plot(dd.core_transport)
    Example block output

    HFS sizing actor changes the thickness of the OH and TF layers on the high field side to satisfy current and stresses constraints

    plot(dd.build)
 FUSE.ActorHFSsizing(dd, act);
-plot!(dd.build; cx=false)
    Example block output

    The stresses on the center stack are stored in the solid_mechanics IDS

    plot(dd.solid_mechanics.center_stack.stress)
    Example block output

    LFS sizing actors change location of the outer TF leg to meet ripple requirements

    plot(dd.build)
+plot!(dd.build; cx=false)
    Example block output

    The stresses on the center stack are stored in the solid_mechanics IDS

    plot(dd.solid_mechanics.center_stack.stress)
    Example block output

    LFS sizing actors change location of the outer TF leg to meet ripple requirements

    plot(dd.build)
 FUSE.ActorLFSsizing(dd, act);
-plot!(dd.build; cx=false)
    Example block output

    A custom show() method is defined to print the summary of dd.build.layer

    dd.build.layer
    23×10 DataFrame
+plot!(dd.build; cx=false)
    Example block output

    A custom show() method is defined to print the summary of dd.build.layer

    dd.build.layer
    23×10 DataFrame
  Row │ group   details                            type      ΔR        R_start   R_end     material      area        volume     shape
      │ String  String                             String    Float64   Float64   Float64   String        Float64     Float64    String
 ─────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────
-   1 │ in                                                   2.26595    0.0       2.26595  steel          24.4421     138.231
-   2 │ in                                         oh        0.251772   2.26595   2.51772  nb3sn           7.36386     95.8389
-   3 │ hfs                                        tf        0.293854   2.51772   2.81157  nb3sn_kdemo    17.5432     309.912   convex hull
+   1 │ in                                                   2.26544    0.0       2.26544  steel          24.4421     138.231
+   2 │ in                                         oh        0.251717   2.26544   2.51716  nb3sn           7.36386     95.8389
+   3 │ hfs                                        tf        0.294412   2.51716   2.81157  nb3sn_kdemo    17.5432     309.912   convex hull
    4 │ hfs     gap tf vacuum vessel                         0.210263   2.81157   3.02183  vacuum          7.41625    309.892   double ellipse
    5 │ hfs     vacuum vessel  outer               wall      0.030508   3.02183   3.05234  steel           1.05298     44.0194  negative offset
    6 │ hfs     vacuum                             vessel    0.201812   3.05234   3.25416  water           6.81818    285.164   negative offset
@@ -367,17 +399,17 @@
   18 │ lfs     vacuum                             vessel    0.201812  10.9037   11.1055   water           6.81818    285.164   negative offset
   19 │ lfs     vacuum vessel  outer               wall      0.030508  11.1055   11.136    steel           1.05298     44.0194  negative offset
   20 │ lfs     gap tf vacuum vessel                         0.210263  11.136    11.3463   vacuum          7.41625    309.892   double ellipse
-  21 │ lfs                                        tf        0.293854  11.3463   11.6402   nb3sn_kdemo    17.541      309.873   convex hull
-  22 │ out                                                  2.16943   11.6402   13.8096   vacuum        124.041     6312.85
-  23 │ out                                        cryostat  0.32353   13.8096   14.1331   steel          10.643      717.73    silo

    ActorHFSsizing and ActorLFSsizing only change the layer's thicknesses, so we then need to trigger a build of the 2D cross-sections after them:

    FUSE.ActorCXbuild(dd, act);
-plot(dd.build)
    Example block output

    Generate passive structures information (for now the vacuum vessel)

    FUSE.ActorPassiveStructures(dd, act)
-plot(dd.pf_passive)
    Example block output

    We can now give the PF coils their final position given the new build

    actor = FUSE.ActorPFdesign(dd, act);
-plot(actor)
    Example block output

    With information about both pfactive and pfpassive we can now evaluate vertical stability

    ActorVerticalStability(dd, act)
+  21 │ lfs                                        tf        0.294412  11.3463   11.6407   nb3sn_kdemo    17.541      309.873   convex hull
+  22 │ out                                                  2.16943   11.6407   13.8101   vacuum        124.041     6312.85
+  23 │ out                                        cryostat  0.32353   13.8101   14.1337   steel          10.643      717.73    silo

    ActorHFSsizing and ActorLFSsizing only change the layer's thicknesses, so we then need to trigger a build of the 2D cross-sections after them:

    FUSE.ActorCXbuild(dd, act);
+plot(dd.build)
    Example block output

    Generate passive structures information (for now the vacuum vessel)

    FUSE.ActorPassiveStructures(dd, act)
+plot(dd.pf_passive)
    Example block output

    We can now give the PF coils their final position given the new build

    actor = FUSE.ActorPFdesign(dd, act);
+plot(actor)
    Example block output

    With information about both pfactive and pfpassive we can now evaluate vertical stability

    ActorVerticalStability(dd, act)
 IMAS.freeze(dd.mhd_linear)

    The ActorNeutronics calculates the heat flux on the first wall

    FUSE.ActorNeutronics(dd, act);
 p = plot(; layout=2, size=(900, 350))
 plot!(p, dd.neutronics.time_slice[].wall_loading, subplot=1)
 plot!(p, FUSE.define_neutrons(dd, 100000)[1], dd.equilibrium.time_slice[]; subplot=1, colorbar_entry=false)
-plot!(p, dd.neutronics.time_slice[].wall_loading; cx=false, subplot=2, ylabel="")
    Example block output

    The ActorBlanket will change the thickess of the first wall, breeder, shield, and Li6 enrichment to achieve target TBR

    FUSE.ActorBlanket(dd, act);
+plot!(p, dd.neutronics.time_slice[].wall_loading; cx=false, subplot=2, ylabel="")
    Example block output

    The ActorBlanket will change the thickess of the first wall, breeder, shield, and Li6 enrichment to achieve target TBR

    FUSE.ActorBlanket(dd, act);
 print_tree(IMAS.freeze(dd.blanket); maxdepth=5)
    actors: Blanket
 actors:  CXbuild
 blanket
@@ -389,42 +421,42 @@
 │     │  │  ├─ midplane_thickness ➡ 0.02 [m]
 │     │  │  └─ name ➡ "lfs first wall"
 │     │  ├─ 2
-│     │  │  ├─ material ➡ "lithium-lead: Li6/7=24.551"
+│     │  │  ├─ material ➡ "lithium-lead: Li6/7=24.222"
 │     │  │  ├─ midplane_thickness ➡ 1.16754 [m]
 │     │  │  └─ name ➡ "lfs blanket"
 │     │  └─ 3
 │     │     ├─ material ➡ "steel"
-│     │     ├─ midplane_thickness ➡ 0.558741 [m]
+│     │     ├─ midplane_thickness ➡ 0.55942 [m]
 │     │     └─ name ➡ "lfs high temp shield"
 │     ├─ name ➡ "blanket"
 │     └─ time_slice
 │        └─ 1
-│           ├─ peak_escape_flux ➡ 688717 [W/m^2]
-│           ├─ peak_wall_flux ➡ 2.00273e+06 [W/m^2]
-│           ├─ power_incident_neutrons ➡ 2.0329e+08 [W]
+│           ├─ peak_escape_flux ➡ 638725 [W/m^2]
+│           ├─ peak_wall_flux ➡ 1.94708e+06 [W/m^2]
+│           ├─ power_incident_neutrons ➡ 1.92503e+08 [W]
 │           ├─ power_incident_radiated ➡ 0 [W]
-│           ├─ power_thermal_extracted ➡ 2.43948e+08 [W]
-│           ├─ power_thermal_neutrons ➡ 2.43948e+08 [W]
+│           ├─ power_thermal_extracted ➡ 2.31004e+08 [W]
+│           ├─ power_thermal_neutrons ➡ 2.31004e+08 [W]
 │           ├─ power_thermal_radiated ➡ 0 [W]
 │           ├─ time ➡ 0 [s]
-│           └─ tritium_breeding_ratio ➡ 1.26507
+│           └─ tritium_breeding_ratio ➡ 1.2614
 ├─ time ➡ [0] [s]
-└─ tritium_breeding_ratio ➡ [1.1912]

    The ActorDivertors actor calculates the divertors heat flux

    FUSE.ActorDivertors(dd, act);
+└─ tritium_breeding_ratio ➡ [1.18378]

    The ActorDivertors actor calculates the divertors heat flux

    FUSE.ActorDivertors(dd, act);
 print_tree(IMAS.freeze(dd.divertors); maxdepth=4)
    actors: Divertors
 divertors
 ├─ divertor
 │  └─ 1
 │     ├─ power_conducted
-│     │  ├─ data ➡ [1.19259e+08] [W]
+│     │  ├─ data ➡ [1.16884e+08] [W]
 │     │  └─ time ➡ [0] [s]
 │     ├─ power_convected
 │     │  ├─ data ➡ [0] [W]
 │     │  └─ time ➡ [0] [s]
 │     ├─ power_incident
-│     │  ├─ data ➡ [4.29947e+07] [W]
+│     │  ├─ data ➡ [3.90606e+07] [W]
 │     │  └─ time ➡ [0] [s]
 │     ├─ power_thermal_extracted
-│     │  ├─ data ➡ [4.29947e+07] [W]
+│     │  ├─ data ➡ [3.90606e+07] [W]
 │     │  └─ time ➡ [0] [s]
 │     └─ target
 │        ├─ 1
@@ -435,107 +467,107 @@
 │
 └─ time ➡ [0] [s]

    The ActorBalanceOfPlant calculates the optimal cooling flow rates for the heat sources (breeder, divertor, and wall) and get an efficiency for the electricity conversion cycle

    actor = FUSE.ActorBalanceOfPlant(dd, act);
 plot(actor)

    ActorCosting will break down the capital and operational costs

    FUSE.ActorCosting(dd, act)
-plot(dd.costing)
    Example block output

    Let's checkpoint our results

    @checkin chk :manual dd ini act

    Saving and loading data

    tutorial_temp_dir = tempdir()
+plot(dd.costing)
    Example block output

    Let's checkpoint our results

    @checkin chk :manual dd ini act

    Saving and loading data

    tutorial_temp_dir = tempdir()
 filename = joinpath(tutorial_temp_dir, "$(ini.general.casename).json")
    "/tmp/K-DEMO.json"

    When saving data to be shared outside of FUSE, one can set freeze=true so that all expressions in the dd are evaluated and saved to file.

    IMAS.imas2json(dd, filename; freeze=false, strict=false);

    Load from JSON

    dd1 = IMAS.json2imas(filename);

    Comparing two IDSs

    We can introduce a change in the dd1 and spot it with the diff function

    dd1.equilibrium.time_slice[1].time = -100.0
 IMAS.diff(dd.equilibrium, dd1.equilibrium)
    Dict{String, String} with 1 entry:
   "time_slice[1].time" => "value:  -Inf --  -100.0"

    Summary

    Snapshot of dd in 0D quantities (evaluated at dd.global_time)

    FUSE.extract(dd)
    GEOMETRY                               EQUILIBRIUM                            TEMPERATURES                           
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────    
-R0 → 6.5 [m]                           B0 → 7.8 [T]                           Te0 → 20.4 [keV]                       
-a → 2.01 [m]                           ip → 12 [MA]                           Ti0 → 19.5 [keV]                       
-1/ϵ → 3.24                             q95 → 5.98                             <Te> → 9.34 [keV]                      
-κ → 1.85                               <Bpol> → 0.802 [T]                     <Ti> → 8.28 [keV]                      
-δ → 0.481                              βpol_MHD → 0.854                       Te0/<Te> → 2.19                        
-ζ → -0.0185                            βtor_MHD → 0.00891                     Ti0/<Ti> → 2.36                        
-Volume → 909 [m³]                      βn_MHD → 1.17                                                                 
+R0 → 6.5 [m]                           B0 → 7.8 [T]                           Te0 → 19.6 [keV]                       
+a → 2.01 [m]                           ip → 12 [MA]                           Ti0 → 18.7 [keV]                       
+1/ϵ → 3.24                             q95 → 6.1                              <Te> → 9.08 [keV]                      
+κ → 1.85                               <Bpol> → 0.803 [T]                     <Ti> → 8.07 [keV]                      
+δ → 0.481                              βpol_MHD → 0.835                       Te0/<Te> → 2.16                        
+ζ → -0.0185                            βtor_MHD → 0.00872                     Ti0/<Ti> → 2.31                        
+Volume → 911 [m³]                      βn_MHD → 1.14                                                                 
 Surface → 739 [m²]                                                                                                   
                                                                                                                      
 DENSITIES                              PRESSURES                              TRANSPORT                              
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────    
-ne0 → 8.81e+19 [m⁻³]                   P0 → 0.623 [MPa]                       τe → 1.84 [s]                          
-ne_ped → 6.4e+19 [m⁻³]                 <P> → 0.218 [MPa]                      τe_exp → 2.38 [s]                      
-ne_line → 7.91e+19 [m⁻³]               P0/<P> → 2.86                          H98y2 → 0.881                          
-<ne> → 7.25e+19 [m⁻³]                  βn → 1.17                              H98y2_exp → 0.954                      
-ne0/<ne> → 1.21                        βn_th → 1.12                           Hds03 → 0.665                          
-fGW → 0.835                                                                   Hds03_exp → 0.747                      
-zeff_ped → 2                                                                  τα_thermalization → 0.899 [s]          
-<zeff> → 2                                                                    τα_slowing_down → 1.17 [s]             
+ne0 → 8.84e+19 [m⁻³]                   P0 → 0.593 [MPa]                       τe → 1.84 [s]                          
+ne_ped → 6.4e+19 [m⁻³]                 <P> → 0.213 [MPa]                      τe_exp → 2.38 [s]                      
+ne_line → 8.02e+19 [m⁻³]               P0/<P> → 2.78                          H98y2 → 0.863                          
+<ne> → 7.36e+19 [m⁻³]                  βn → 1.15                              H98y2_exp → 0.935                      
+ne0/<ne> → 1.2                         βn_th → 1.1                            Hds03 → 0.652                          
+fGW → 0.846                                                                   Hds03_exp → 0.733                      
+zeff_ped → 2                                                                  τα_thermalization → 0.863 [s]          
+<zeff> → 2                                                                    τα_slowing_down → 1.09 [s]             
 impurities → DT Ne20 He4                                                                                             
                                                                                                                      
 SOURCES                                EXHAUST                                CURRENTS                               
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────    
-Pec → 50 [MW]                          Psol → 119 [MW]                        ip_bs_aux_ohm → 12 [MA]                
-rho0_ec → 0.5 [MW]                     PLH → 63.6 [MW]                        ip_ni → 6.73 [MA]                      
-PnbiNaN [MW]                        Bpol_omp → 1.16 [T]                    ip_bs → 3.12 [MA]                      
-Enbi1NaN [MeV]                      λq → 0.948 [mm]                        ip_aux → 3.6 [MA]                      
-Pic → 50 [MW]                          qpol → 2.35e+03 [MW/m²]                ip_ohm → 5.29 [MA]                     
-PlhNaN [MW]                         qpar → 1.23e+04 [MW/m²]                ejima → 0.4                            
-Paux_tot → 100 [MW]                    P/R0 → 18.3 [MW/m]                     flattop → 0.5 [Hours]                  
- → 54 [MW]                           PB/R0 → 143 [MW T/m]                                                          
-Pohm → 0.0747 [MW]                     PBp/R0 → 14.7 [MW T/m]                                                        
-Pheat → 154 [MW]                       PBϵ/R0q95 → 7.4 [MW T/m]                                                      
-Prad_tot → -34.8 [MW]                  neutrons_peak → 0.363 [MW/m²]                                                 
+Pec → 50 [MW]                          Psol → 117 [MW]                        ip_bs_aux_ohm → 12 [MA]                
+rho0_ec → 0.5 [MW]                     PLH → 64.3 [MW]                        ip_ni → 6.71 [MA]                      
+PnbiNaN [MW]                        Bpol_omp → 1.17 [T]                    ip_bs → 2.97 [MA]                      
+Enbi1NaN [MeV]                      λq → 0.938 [mm]                        ip_aux → 3.74 [MA]                     
+Pic → 50 [MW]                          qpol → 2.33e+03 [MW/m²]                ip_ohm → 5.27 [MA]                     
+PlhNaN [MW]                         qpar → 1.21e+04 [MW/m²]                ejima → 0.4                            
+Paux_tot → 100 [MW]                    P/R0 → 18 [MW/m]                       flattop → 0.5 [Hours]                  
+ → 51.3 [MW]                         PB/R0 → 140 [MW T/m]                                                          
+Pohm → 0.0775 [MW]                     PBp/R0 → 14.4 [MW T/m]                                                        
+Pheat → 151 [MW]                       PBϵ/R0q95 → 7.11 [MW T/m]                                                     
+Prad_tot → -34.5 [MW]                  neutrons_peak → 0.353 [MW/m²]                                                 
                                                                                                                      
 BOP                                    BUILD                                  COSTING                                
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────    
-Pfusion → 270 [MW]                     PF_material → nb3sn                    capital_cost → 4.58 [$B]               
-Qfusion → 2.7                          TF_material → nb3sn_kdemo              levelized_CoE → Inf [$/kWh]            
-thermal_cycle_type → rankine           OH_material → nb3sn                    TF_of_total → 4.51 [%]                 
-thermal_efficiency_plant → 34.1 [%]    TF_max_b → 18.1 [T]                    BOP_of_total → 5.25 [%]                
-thermal_efficiency_cycleNaN [%]     OH_max_b → 4.19 [T]                    blanket_of_total → 22.6 [%]            
-power_electric_generated → 110 [MW]    TF_j_margin → 1.4                      cryostat_of_total → 7.13 [%]           
-Pelectric_net → -35.4 [MW]             OH_j_margin → 14.3                                                            
-Qplant → 0.756                         TF_stress_margin → 2.12                                                       
-TBR → 1.19                             OH_stress_margin → 2.61                                                       
+Pfusion → 256 [MW]                     PF_material → nb3sn                    capital_cost → 4.43 [$B]               
+Qfusion → 2.56                         TF_material → nb3sn_kdemo              levelized_CoE → Inf [$/kWh]            
+thermal_cycle_type → rankine           OH_material → nb3sn                    TF_of_total → 4.64 [%]                 
+thermal_efficiency_plant → 34.1 [%]    TF_max_b → 18.1 [T]                    BOP_of_total → 5.24 [%]                
+thermal_efficiency_cycleNaN [%]     OH_max_b → 4.24 [T]                    blanket_of_total → 23.4 [%]            
+power_electric_generated → 104 [MW]    TF_j_margin → 1.4                      cryostat_of_total → 7.38 [%]           
+Pelectric_net → -41.2 [MW]             OH_j_margin → 6.75                                                            
+Qplant → 0.716                         TF_stress_margin → 2.12                                                       
+TBR → 1.18                             OH_stress_margin → 3.26

    Extract + plots saved to PDF (or printed to screen it filename is omitted)

    filename = joinpath(tutorial_temp_dir, "$(ini.general.casename).pdf")
 FUSE.digest(dd)#, filename)
    GEOMETRY                               EQUILIBRIUM                            TEMPERATURES
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────
-R0 → 6.5 [m]                           B0 → 7.8 [T]                           Te0 → 20.4 [keV]
-a → 2.01 [m]                           ip → 12 [MA]                           Ti0 → 19.5 [keV]
-1/ϵ → 3.24                             q95 → 5.98                             <Te> → 9.34 [keV]
-κ → 1.85                               <Bpol> → 0.802 [T]                     <Ti> → 8.28 [keV]
-δ → 0.481                              βpol_MHD → 0.854                       Te0/<Te> → 2.19
-ζ → -0.0185                            βtor_MHD → 0.00891                     Ti0/<Ti> → 2.36
-Volume → 909 [m³]                      βn_MHD → 1.17
+R0 → 6.5 [m]                           B0 → 7.8 [T]                           Te0 → 19.6 [keV]
+a → 2.01 [m]                           ip → 12 [MA]                           Ti0 → 18.7 [keV]
+1/ϵ → 3.24                             q95 → 6.1                              <Te> → 9.08 [keV]
+κ → 1.85                               <Bpol> → 0.803 [T]                     <Ti> → 8.07 [keV]
+δ → 0.481                              βpol_MHD → 0.835                       Te0/<Te> → 2.16
+ζ → -0.0185                            βtor_MHD → 0.00872                     Ti0/<Ti> → 2.31
+Volume → 911 [m³]                      βn_MHD → 1.14
 Surface → 739 [m²]
 
 DENSITIES                              PRESSURES                              TRANSPORT
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────
-ne0 → 8.81e+19 [m⁻³]                   P0 → 0.623 [MPa]                       τe → 1.84 [s]
-ne_ped → 6.4e+19 [m⁻³]                 <P> → 0.218 [MPa]                      τe_exp → 2.38 [s]
-ne_line → 7.91e+19 [m⁻³]               P0/<P> → 2.86                          H98y2 → 0.881
-<ne> → 7.25e+19 [m⁻³]                  βn → 1.17                              H98y2_exp → 0.954
-ne0/<ne> → 1.21                        βn_th → 1.12                           Hds03 → 0.665
-fGW → 0.835                                                                   Hds03_exp → 0.747
-zeff_ped → 2                                                                  τα_thermalization → 0.899 [s]
-<zeff> → 2                                                                    τα_slowing_down → 1.17 [s]
+ne0 → 8.84e+19 [m⁻³]                   P0 → 0.593 [MPa]                       τe → 1.84 [s]
+ne_ped → 6.4e+19 [m⁻³]                 <P> → 0.213 [MPa]                      τe_exp → 2.38 [s]
+ne_line → 8.02e+19 [m⁻³]               P0/<P> → 2.78                          H98y2 → 0.863
+<ne> → 7.36e+19 [m⁻³]                  βn → 1.15                              H98y2_exp → 0.935
+ne0/<ne> → 1.2                         βn_th → 1.1                            Hds03 → 0.652
+fGW → 0.846                                                                   Hds03_exp → 0.733
+zeff_ped → 2                                                                  τα_thermalization → 0.863 [s]
+<zeff> → 2                                                                    τα_slowing_down → 1.09 [s]
 impurities → DT Ne20 He4
 
 SOURCES                                EXHAUST                                CURRENTS
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────
-Pec → 50 [MW]                          Psol → 119 [MW]                        ip_bs_aux_ohm → 12 [MA]
-rho0_ec → 0.5 [MW]                     PLH → 63.6 [MW]                        ip_ni → 6.73 [MA]
-Pnbi → NaN [MW]                        Bpol_omp → 1.16 [T]                    ip_bs → 3.12 [MA]
-Enbi1 → NaN [MeV]                      λq → 0.948 [mm]                        ip_aux → 3.6 [MA]
-Pic → 50 [MW]                          qpol → 2.35e+03 [MW/m²]                ip_ohm → 5.29 [MA]
-Plh → NaN [MW]                         qpar → 1.23e+04 [MW/m²]                ejima → 0.4
-Paux_tot → 100 [MW]                    P/R0 → 18.3 [MW/m]                     flattop → 0.5 [Hours]
-Pα → 54 [MW]                           PB/R0 → 143 [MW T/m]
-Pohm → 0.0747 [MW]                     PBp/R0 → 14.7 [MW T/m]
-Pheat → 154 [MW]                       PBϵ/R0q95 → 7.4 [MW T/m]
-Prad_tot → -34.8 [MW]                  neutrons_peak → 0.363 [MW/m²]
+Pec → 50 [MW]                          Psol → 117 [MW]                        ip_bs_aux_ohm → 12 [MA]
+rho0_ec → 0.5 [MW]                     PLH → 64.3 [MW]                        ip_ni → 6.71 [MA]
+Pnbi → NaN [MW]                        Bpol_omp → 1.17 [T]                    ip_bs → 2.97 [MA]
+Enbi1 → NaN [MeV]                      λq → 0.938 [mm]                        ip_aux → 3.74 [MA]
+Pic → 50 [MW]                          qpol → 2.33e+03 [MW/m²]                ip_ohm → 5.27 [MA]
+Plh → NaN [MW]                         qpar → 1.21e+04 [MW/m²]                ejima → 0.4
+Paux_tot → 100 [MW]                    P/R0 → 18 [MW/m]                       flattop → 0.5 [Hours]
+Pα → 51.3 [MW]                         PB/R0 → 140 [MW T/m]
+Pohm → 0.0775 [MW]                     PBp/R0 → 14.4 [MW T/m]
+Pheat → 151 [MW]                       PBϵ/R0q95 → 7.11 [MW T/m]
+Prad_tot → -34.5 [MW]                  neutrons_peak → 0.353 [MW/m²]
 
 BOP                                    BUILD                                  COSTING
 ───────────────────────────────────    ───────────────────────────────────    ───────────────────────────────────
-Pfusion → 270 [MW]                     PF_material → nb3sn                    capital_cost → 4.58 [$B]
-Qfusion → 2.7                          TF_material → nb3sn_kdemo              levelized_CoE → Inf [$/kWh]
-thermal_cycle_type → rankine           OH_material → nb3sn                    TF_of_total → 4.51 [%]
-thermal_efficiency_plant → 34.1 [%]    TF_max_b → 18.1 [T]                    BOP_of_total → 5.25 [%]
-thermal_efficiency_cycle → NaN [%]     OH_max_b → 4.19 [T]                    blanket_of_total → 22.6 [%]
-power_electric_generated → 110 [MW]    TF_j_margin → 1.4                      cryostat_of_total → 7.13 [%]
-Pelectric_net → -35.4 [MW]             OH_j_margin → 14.3
-Qplant → 0.756                         TF_stress_margin → 2.12
-TBR → 1.19                             OH_stress_margin → 2.61
+Pfusion → 256 [MW]                     PF_material → nb3sn                    capital_cost → 4.43 [$B]
+Qfusion → 2.56                         TF_material → nb3sn_kdemo              levelized_CoE → Inf [$/kWh]
+thermal_cycle_type → rankine           OH_material → nb3sn                    TF_of_total → 4.64 [%]
+thermal_efficiency_plant → 34.1 [%]    TF_max_b → 18.1 [T]                    BOP_of_total → 5.24 [%]
+thermal_efficiency_cycle → NaN [%]     OH_max_b → 4.24 [T]                    blanket_of_total → 23.4 [%]
+power_electric_generated → 104 [MW]    TF_j_margin → 1.4                      cryostat_of_total → 7.38 [%]
+Pelectric_net → -41.2 [MW]             OH_j_margin → 6.75
+Qplant → 0.716                         TF_stress_margin → 2.12
+TBR → 1.18                             OH_stress_margin → 3.26
 
 @ time = 0.0 [s]
 ​
@@ -566,4 +598,4 @@
 GKS: could not find font middle.ttf
 ​
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